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Transcript
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E XEMPL
OBLEMS
XEMPLAR
PROBLEMS
XEMPLAR PR
CHEMIS
TRY
CHEMISTRY
no
Class XI
FOREWORD
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The National Curriculum Framework (NCF) 2005 initiated a new phase of
development of syllabi and textbooks for all stages of school education. In this
phase, a conscious effort has been made to discourage rote learning and to enhance
comprehension. This is well in tune with the NPE-1986 and Learning Without
Burden-1993 that recommend child centred system of education. The textbooks
for Class XI were released in 2006 and for Class XII in 2007. Overall the books
have been well received by students and teachers.
NCF-2005 notes that treating the prescribed textbooks as the sole basis of
examination is one of the key reasons why other resources and sites of learning are
ignored. It further reiterates that the methods used for teaching and evaluation will
also determine how effective these textbooks prove for making children’s life at
school a happy experience, rather than source of stress or boredom. It calls for
reform in examination system currently prevailing in the country.
The position papers of the National Focus Groups on Teaching of Science,
Teaching of Mathematics and Examination Reforms envisage that the question
papers, set in annual examinations conducted by the various Boards do not really
assess genuine understanding of the subjects. The quality of question papers is
often not up to the mark. They usually seek mere information based on rote
memorisation, and fail to test higher-order skills like reasoning and analysis, let
alone lateral thinking, creativity, and judgment. Good unconventional questions,
challenging problems and experiment-based problems rarely find a place in question
papers. In order to address to the issue, and also to provide additional learning
material, the Department of Education in Science and Mathematics (DESM) has
made an attempt to develop resource book of exemplar problems in different subjects
at secondary and higher-secondary stages. Each resource book contains different
types of questions of varying difficulty level. Some questions would require the
students to apply simultaneously understanding of more than one concept. These
problems are not meant to serve merely as questions bank for examinations but
are primarily meant to improve the quality of teaching/learning process in schools.
It is expected that these problems would encourage teachers to design quality
questions on their own. Students and teachers should always keep in mind that
examination and assessment should test comprehension, information recall,
analytical thinking and problem-solving ability, creativity and speculative ability.
A team of experts and teachers with an understanding of the subject and a
proper role of examinations worked hard to accomplish this task. The material was
discussed, edited, and finally included in this resource book.
NCERT would welcome suggestions from students, teachers and parents which
would help us to further improve the quality of material in subsequent editions.
New Delhi
May, 2008
Prof. Yash Pal
Chairperson
National Steering Committee
National Council of Educational
Research and Training
PREFACE
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The Department of Education in Science and Mathematics (DESM), National Council
of Educational Research and Training (NCERT), initiated the programme for the
development of ‘Exemplar Problems’ in science and mathematics for secondary
and higher secondary stages based on the subject textbooks developed on the
bases of the NCF-2005. The present book is based on the contents of the Chemistry
Textbook for Class XI published by the Council in 2006.
The main objective of the book on ‘Exemplar Problems in Chemistry’ is to provide
the teachers and students a large number of quality problems in various forms
and format with varying levels of difficulty to facilitate teaching-learning of concepts
in Chemistry that are presented through the Textbook for Class XI. It is envisaged
that the problems included in this book would help the teachers to design tasks to
assess effectiveness of their preparation of balanced question papers for unit and
terminal tests. The feedback based on the analysis of students’ responses may help
the teachers in further improving the quality of classroom instructions. In addition,
the problems given in this book are also expected to help the teachers to perceive
the basic characteristics of good quality questions and motivate them to frame
similar problems on their own. Students can benefit themselves by attempting the
problems given in the book for self assessment and also in mastering the basic
techniques of problem solving. Some of the problems given in the book are expected
to challenge the students’ understanding of Chemistry concepts and to apply them
in new situations. At number of places elaboration of answers may be required.
The problems included in this book were developed in workshop mode organised
by the DESM involving practicing teachers, subject experts from universities and
institutes of higher learning, and the members of the Chemistry group of the DESM
whose names appear separately. I gratefully acknowledge their efforts and thank
them for their valuable contribution in our endeavour to provide good quality
instructional material for the school system. I especially thank Professor Brahm
Parkash, Dr. Alka Mehrotra, Dr. Anjni Koul and Ms. Ruchi Verma of DESM for
editing and refining the problems and for making the manuscript pressworthy.
Thanks are also due to Professor Brahm Parkash of DESM for coordinating this
programme.
no
I also thank Shri Ishwar Singh, Sr. DTP Operator for typing the manuscript
and preparing a press-ready copy.
We look forward to feedback from students, teachers and parents for further
improvement of the contents of the book.
Dr. Hukum Singh
Professor and Head
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DEVELOPMENT TEAM
MEMBERS
Alka Mehrotra, Reader, DESM, NCERT, New Delhi.
Anjni Koul, Sr. Lecturer, DESM, NCERT, New Delhi
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Azhar Aslam Khan, PGT (Chemistry), J. D. Tytlar School, R- Block, New Rajinder
Nagar, Delhi.
K. K. Arora, Reader, Department of Chemistry, Zakir Hussain College, New Delhi.
K. N. Upadhyay, Head (Retd.), Chemistry Department, Ramjas College, University
of Delhi, Delhi.
M. P. Mahajan, Professor, Department of Applied Chemistry, Guru Nanak Dev
University, Amritsar.
Neeti Mishra, Sr. Lecturer, Department of Chemistry, Acharya Narendra Dev College,
Delhi.
S. K. Gupta, Reader, School of Studies in Chemistry, Jiwaji University, Gwalior.
Shah Saddad Hussain, Madipur, New Delhi.
Ruchi Verma, Lecturer, DESM, NCERT, New Delhi.
Sunita Hooda, Reader, Department of Chemistry, Acharya Narendra Dev College,
Govindpuri, Kalkaji, New Delhi.
MEMBER-COORDINATORS
no
Brahm Prakash, Professor, DESM, NCERT, New Delhi.
ACKNOWLEDGEMENT
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The National Council of Educational Research and Training acknowledges
the valuable contributions of the individuals and the organizations involved
in the development of Exemplar Problems in Chemistry for Classes XI. The
following academics contributed very effectively for the review of the
manuscript of this book : B.K. Puri, Professor (Retired), Department of
Chemistry, I.I.T. Delhi; Prof. B. L. Khandelwal, Director, Disha Institute of
Management and Technology, Raipur, Chhattisgarh; B. S. Kapoor, Professor
(Retd.), Department of Chemistry, Delhi University, Delhi; C. S. Pande,
Professor (Retired), Himachal University, Shimla; K. K. Arora, Reader, Zakir
Hussain College, Delhi University, Delhi; M. L. Agarwal, Principal (Retd.),
K. V. Jaipur, Mansarowar, Jaipur, Rajasthan; Nand Kishore, Professor,
Department of Chemistry, I.I.T. Bombay, Powai, Mumbai; Neeti Mishra,
Sr. Lecturer, Acharya Narendra Dev College, Delhi University, Delhi; Puran
Chand, Professor (Retd.), Joint Director, NCERT, New Delhi at present
Consultant NIOS; Sohan Mittal, PGT (Chemistry), Cambridge School, New
Delhi; Sulekh Chandra, Reader, Department of Chemistry, Zakir Hussain
College, New Delhi; Sunita Ramrakhiani, PGT Chemistry, Ahlcon Public School,
Delhi; Tripti Agarwal Jain, Professor and Head, Department of Chemistry,
Disha Institute of Management and Technology, Raipur, Chhattisgarh;
We also acknowledge the contribution of team working for Hindi translation
of the book specially Dr. Alok Chaturvedi, Sr. Lecturer, Department of
Chemistry, Govt. College, Ajmer and Dr. K. K. Sharma, Vice Principal (Retd.),
College of Education, Govt. of Rajasthan, Ajmer for helping us to improve the
English manuscript.
no
Special thanks are also due to Dr. Hukum Singh, Professor and Head,
DESM, NCERT for his administrative support. The Council also acknowledges
the support provided by the APC office of DESM; administraive staff of
DESM; Deepak Kapoor, Incharge, Computer Station, DESM, Ishwar Singh and
Surender Kumar DTP Operator and K. T. Chitralekha, Copy Editor. The efforts
of the Publication Department are also highly appreciated.
C ONTENTS
iii
PREFACE
v
INTRODUCTION
xi
Unit 1
Some Basic Concepts of Chemistry
1
Unit 2
Structure of Atom
14
Unit 3
Classification of Elements and Periodicity in Properties
27
Unit 4
Chemical Bonding and Molecular Structure
39
Unit 5
States of Matter
53
Unit 6
Thermodynamics
68
Unit 7
Equilibrium
86
Unit 8
Redox Reactions
104
Unit 9
Hydrogen
113
Unit 10
The s-Block Elements
125
Unit 11
The p-Block Elements
134
Unit 12
Organic Chemistry
no
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FOREWORD
Some Basic Principles and Techniques
144
Unit 13
Hydrocarbons
161
Unit 14
Environmental Chemistry
176
Model Question Paper
186
Appendices
200
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CONSTITUTION OF INDIA
Part IV A (Article 51 A)
Fundamental Duties
Fundamental Duties – It shall be the duty of every citizen of India —
(a) to abide by the Constitution and respect its ideals and institutions, the National
Flag and the National Anthem;
(b) to cherish and follow the noble ideals which inspired our national struggle for
freedom;
(c) to uphold and protect the sovereignty, unity and integrity of India;
(d) to defend the country and render national service when called upon to do so;
(e) to promote harmony and the spirit of common brotherhood amongst all the people
of India transcending religious, linguistic and regional or sectional diversities; to
renounce practices derogatory to the dignity of women;
(f) to value and preserve the rich heritage of our composite culture;
(g) to protect and improve the natural environment including forests, lakes, rivers,
wildlife and to have compassion for living creatures;
(h) to develop the scientific temper, humanism and the spirit of inquiry and reform;
(i) to safeguard public property and to abjure violence;
(j) to strive towards excellence in all spheres of individual and collective activity so
that the nation constantly rises to higher levels of endeavour and achievement;
no
(k) who is a parent or guardian, to provide opportunities for education to his child or,
as the case may be, ward between the age of six and fourteen years.
I NTRODUCTION
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Assessment of students is an important part of the teaching-learning process. It
helps a teacher to evaluate (i) his/her own teaching and (ii) the achievement of
students in a particular subject. In other words, assessment provides the present
achievement and subsequent guidance to teching-learning. It is also an
instrument to assess the educational progress of learners.
According to Bloom’s taxonomy, there are three domains of educational
objectives (i) cognitive (ii) affective and (iii) psychomotor. Cognitive domain deals
with the educational products and processes.
In the present book, the problems pertaining to cognitive domain have been
included. These are categorised into different classes on the basis of the type of
their construction.
(i)
Multiple choice
(ii)
Matching type
(iii)
Short answer type
(iv)
Long answer type
(v)
Assertion and reason type
(i)
Multiple choice type : Multiple choice questions are widely used in
objective tests for different examinations. A multiple choice question
consists of a stem followed by 4-5 responses.
(a) Stem : The stem is that part in which the task which the students
have to undertake is set out. It may be a direct question or an
incomplete statement.
no
(b) Response : Below the stem of the question, there are a number of
options comprising of the correct answer(s) and distractors. These
should appear to closely resemble with one another. The distractors
distract students. The style of presentation i.e., length, precision etc.
of any response should not provide any clue of its being a correct
answer or a distractor. Correct responses should be arranged
randomly. A good multiple choice question can induce higher order
thinking among students. A number of multiple choice questions
relating to various aspects of the same theme presented as material,
picture or diagram, or a combination of more than one of these
enables the learners to develop multiple abilities.
(ii)
Matching Type : In this type, a premise is to be matched with single
correct response out of a number of responses. It is known as simple
matching. In compound matching, a premise has to be matched with
more than one correct response.
(iii)
Short answer type : This type of questions have a short answer either in
the form of a word or a few sentences or diagram or numerical value or a
combination of these. Good short answer questions involve the use of
action oriented and precise verbs such as, deduce, conclude, classify,
interpret, explain, extrapolate, translate etc. for precision. The words like,
briefly, short notes on etc. are avoided.
(iv)
Long answer type : These questions require long answers to be written
with or without diagram(s). Long answer questions involve the following
tasks to test higher order abilities.
contrast, distinguish, discriminate, and differentiate.
(b)
compare, list similarities/dissimilarities.
(c)
explain, show how and why and give explanatory reasons.
(d)
discuss, defend, refute, prove, disprove, justify.
(e)
judge evaluate.
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(a)
Some Problem Solving questions have also been included in the book. Such
questions require the application of knowledge and procedures to a problem
situation. It is a form of discovery learning, bridging the gap between the learner’s
existing knowledge and the solution to the problem. In problem solving the learner
is required to construct some knowledge to find out the solution of the problem
or investigate a fact or a result.
no
For closed-ended problems, there will only be one answer. For open-ended
problems, there will be more than one answer.
xii
BLUE PRINT OF SAMPLE QUESTION PAPER (CHEMISTRY)
CLASS XI
TOTAL
Environmental Chemistry
14.
Hydrogen
9.
Hydrocarbons
Redox Reactions
8.
13.
Equilibrium
7.
Organic Chemistry - Some
Basic Principles and
Techniques
Thermodynamics
6.
12.
States of Matter
5.
The p-Block Elements
Chemical Bonding and
Molecular Structure
4.
11.
Classification of Elements and
Periodicity in Properties
3.
The s-Block Elements
Structure of Atom
2.
10.
Some Basic Concepts of
Chemistry
1.
Unit/Questions Type
70
3
7
7
5
5
1×2=2
1×1=1
4
1×1=1
4
4
1×1=1
1×1=1
10
1×2=2
1×2=2
1×2=2
1×2=2
2 mark
27
1×3=3
1×3=3
1×3=3
1×3=3
1×3=3
1×3=3
1×3=3
1×3=3
1×3=3
3 mark
Short Answer
5
1×1=1
1×1=1
1 mark
1×2=2
1×1=1
6
1×2=2
2 mark
MCQ
5
1×1=1
1 mark
6
1×2=2
1×2=2
1×2=2
15
1×5=5
1×5=5
1×5=5
Assertion Long
Reason Answer
Unitwise Weightage to Different Forms of Questions
6
5
5
5
5
1
Weightage
to Content
Unit (Marks)
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TIME : 3 HOURS
I. Design of the Sample Question Paper
Total Number of Questions
of Each Type
4
1
2
4
1
1
5
9
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
3
1
1
1
3
1
1
1
Distribution of Different Types of
Questions over the Units
LA
MCQ MCQ SA
SA
SA AR
1
2
1
2
3
MAX. MARKS : 70
II.
Expected Length of Answer and Time Required for Each Form
of Question shall be as Follows :
Expected Expected
Total Number Total Time
Length
Time for
of Questions Expected
Each Question
1.
MCQ (I)
-
2 minutes
4
08 minutes
2.
MCQ (II)
-
3 minutes
2
06 minutes
3.
SA (I)
one line
3 minutes
4
12 minutes
4.
4.
6.
7.
8.
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Sl. Forms of
No. Questions
SA (II)
20-30
words
4 minutes
5
20 minutes
SA (III)
30-50
words
7 minutes
9
63 minutes
3 minutes
3
09 minutes
15 minutes
3
45 minutes
Assertion-Reason -
Long Answer Type 70-100
words
Revision
-
TOTAL
III.
Sl.
No.
1.
2.
-
30
180 minutes
Weightage to Difficulty Level of Questions
Estimated Difficulty Level of Questions
Percentage
Easy
18
Average
64
Difficult
18
no
3.
17 minutes
MODEL QUESTION PAPER
CHEMISTRY
Class XI
Time : 3 Hours
Maximum Marks : 70
General Instructions :
All the questions are compulsory.
Questions 1 to 4, carry one mark each and questions 5 and 6, carry 2 marks.
Questions 7 to 10 are short answer questions carrying one mark each.
Questions 11 to 15 are also short answer questions carrying two marks each.
Questions 16 to 24 are also short answer questions carrying three marks each.
Questions 25 to 27 are assertion- reason questions carry two marks each.
Questions 28 to 30 are long answer questions and carry five marks each.
Use log tables for calculations if necessary.
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(i)
(ii)
(iii)
(iv)
(v)
(vi)
(vii)
(viii)
Note : Choose one correct option for questions 1 to 4.
1.
The pressure volume work for an ideal gas can be calculated by using the
expression;
V
f
w = − ∫ p ex dV
V
i
The work can also be calculated from the pV plot by using the area under the
curve within the specified limit. When an ideal gas is compressed reversibly
or irreversibly from volume Vi to Vf , which of the following is correct?
2.
(i)
wrev = w irrev
(ii)
wrev < w irrev
(iii)
wrev > w irrev
(iv)
wrev = wirrev + pex. dV
(1)
When hydrochloric acid is added to cobalt nitrate solution at room
temperature, the following reaction takes place :
–
[Co(H2O)6] +3 (aq) + 4Cl (aq) U [CoCl 4 ]2– (aq ) + 6H 2O (l )
blue
no
Pink
The solution is blue at room temperature. However, it turns pink when cooled
in a freezing mixture. Based upon this information, which of the following
expression is correct for the forward reaction?
(i)
ΔH > 0
(ii)
ΔH < 0
(iii)
ΔH = 0
(iv)
The sign of ΔH cannot be predicted
on the basis of this information.
(1)
3.
Which of the following elements does not form hydride by direct heating with
dihydrogen?
(i)
Be
(ii)
Mg
(iii)
Sr
(iv)
Ba
(1)
4. Which of the following species should be aromatic in character?
(ii)
(iii)
(iv)
(1)
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(i)
Note : Choose two correct options for questions 5 and 6.
5. Identify the pairs which are of isotopes?
(i)
(ii)
12
35
17
(iii)
14
(iv)
8
6
4
13
X,
6
6
X,
37
Y
17
14
X,
X,
Y
7
8
5
Y
Y
(2)
6. Electrophiles are electron seeking species. Which of the following sets consist
of electrophiles only.
(i)
BF 3, NH3 , H2O
(ii)
AlCl 3, SO 3 ,
(iii)
,
(iv)
,
, C2H5,
(2)
7. How many significant figures should be present in the answer of the following
calculations?
no
2.5 × 1.25 × 3.5
2.01
8. Complete the following reactions
(i)
O 2 + H2O ⎯→
(ii)
O 2– + H2O ⎯→
(1)
(1)
2–
189 Model Question Paper
9. Give IUPAC name of the compound whose line formula is given below:
(1)
10. Green house effect leads to global warming. Which substances are responsible
for green house effect?
(1)
11. Using molecular orbital theory, compare the bond energy and magnetic
+
–
(2)
character of O 2 and O2 species.
(2)
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12. Consider the reaction given below :
CaCO3 (s) ⎯→ CaO (s) + CO2 (g)
Predict the effect of increase in temperature on the equilibrium constant of
this reaction.
V
Given that Δ f H [CaO(s)] = –635.1 kJ mol
–1
Δf HV [CO2(g)] = –393.5 kJ mol–1
V
Δ f H [CaCO 3(s)] = –1206.9 kJ mol
–1
13. pH of 0.08 mol dm–3 HOCl solution is 2.85. Calculate its ionization constant. (2)
14. Nitric acid is an oxidising agent and reacts with PbO but it does not react
with PbO2. Explain why?
(2)
15. Calculate the strength of 5 volume H 2O 2 solution.
(2)
16. According to de Broglie, matter should exhibit dual behaviour, that is both
particle and wave like properties. However, a cricket ball of 100g does not move
like a wave when it is thrown by a bowler at a speed of 100km/h. Calculate the
wavelength of the ball and explain why it does not show wave nature.
(3)
17. Explain why nitrogen has positive electron gain enthalpy whereas oxygen
has negative, although first ionisation enthalpy of oxygen is lower than that
of nitrogen. Justify your answer.
(3)
18. Write Lewis structure of the following compounds and show formal charge on
each atom.
(3)
no
HNO3, NO2, H2SO 4
19. Although heat is a path function, even then heat absorbed by the system
under certain conditions is independent of path. What are those conditions?
Explain.
(3)
–11
20. The solubility product of Al (OH)3 is 2.7 × 10 . Calculate its solubility in g L–1
and also find out pH of this solution. (Atomic mass of Al is 27 u).
(3)
Exemplar Problems, Chemistry 190
21. Calculate the oxidation number of each sulphur atom in the following
compounds:
(a) Na2S2O3
22.
(b) Na2S4O 6
(3)
(i) Dihydrogen reacts with dioxygen to form water. Name the product and
write its formula when the isotope of hydrogen, which has one proton
and one neutron in its nuclus, is treated with dioxygen?
(1)
(ii) Will the reactivity of both the isotopes of hydrogen be the same towards
oxygen ? Justify your answer.
(2)
(i) Beryllium sulphate and magnesium sulphate are readily soluble in water
whereas the sulphates of barium, calcium and strontium are only
sparingly soluble. Explain.
(2)
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23.
(ii) Why is the temperature maintained around 393 K during the preparation
of plaster of paris?
(1)
24. Give the reactions involved in the preparation of propane from the following :
(3)
(i)
CH3—CH = CH2
(ii)
CH3 CH2 CH2 Cl
(iii)
CH3 CH2 CH2 COO Na
–
+
25. Assertion (A) : The first ionization enthalpy of alkali metals decreases down
the group.
Reason (R) :
Increase in number of orbitals increases the shielding effect
which outweighs the increasing nuclear charge, therefore, the
removal of outermost electron requires less energy on moving
down the group.
(2)
(i)
A and R both are correct but R is not the explanation of A.
(ii)
A is false but R is correct.
(iii)
A and R both are correct and R is the correct explanation of A.
(iv)
A and R both are incorrect.
26. Assertion (A) : Nitration of benzene requires the use of concentrated
sulphuric acid and nitric acid.
The mixture of acids produces the electrophile for the reaction.
(2)
no
Reason (R) :
(i)
A and R both are correct but R is not the explanation of A.
(ii)
A is false but R is correct.
(iii)
A and R both are correct and R is the correct explanation of A.
(iv)
A and R both are incorrect.
27. Assertion (A) : Ozone is destroyed by solar radiations in upper stratosphere.
Reason (R) :
Thinning of ozone layer allows excessive UV radiations to
reach the surface of earth.
(2)
191 Model Question Paper
(i)
A and R both are correct but R is not the explanation of A.
(ii)
A is false but R is correct.
(iii)
A and R both are correct and R is the correct explanation of A.
(iv)
A and R both are incorrect.
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28. (a) Liquids can be considered as very dense gases. When a liquid phase
changes to gas phase, the liquid and the gas phases are in equilibrium
and a surface separates the two phases. This surface is visible if both
phases are in equilibrium and are below critical tempertaure and pressure.
However, it is possible to interconvert liquid and gas wherein two phases
are never present together.
With the help of a well-labled diagram show that CO2 gas can be liquified
by changing the pressure and temperature without passing through the
situation when both gaseous and liquid CO2 are at equilibrium.
(3)
(b) Arrange the following liquids in increasing order of their viscosities. Give
reason for your answer.
(2)
Water, benzene, ethane-1,2-diol.
29.
(a)
(b)
Explain why :
(i)
BCl3 is a Lewis acid.
(ii)
Boric acid is a monobasic acid.
(2)
Compound ‘A’ of boron reacts with excess NH3 to give a compound ‘B’.
Compound ‘B’ on heating gives cyclic compound ‘C’. Compound C is
called inorganic benzene.
(i)
Identify compounds ‘A’, ‘B’ and ‘C’
(ii)
Give the reactions involved in these processes.
(3)
30. (a) Write two important differences between inductive and resonance effects.
(2)
(b)
Give reasons to explain the following observations:
(i)
Carbon number ‘2’ in CH3CH2Cl has more positive charge than that
in CH3CH2Br.
(ii)
CH3–CH = CH–CH = CH2 (I) is more stable than
no
CH3–CH = CH–CH2–CH = CH 2 (II).
Exemplar Problems, Chemistry 192
(3)
Guidelines for Evaluation (Marking Scheme)
1.
(ii)
(1)
2.
(i)
(1)
3.
(i)
(1)
4.
(iv)
(1)
5.
6.
7.
8.
9.
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• For questions 5 and 6 two marks for both correct answers, otherwise
zero mark
(i) and (ii)
(2)
(ii) and (iii)
(2)
Two
(1)
(i)
O22– + 2H2O ⎯→ 2OH– + H2O 2
(ii)
2O2– + 2H2O ⎯→ 2OH– + H2O2 + O2
(1)
(½ + ½)
4-Methylhept–5–en–2–one
(1)
10.
Trapping of heat by green house gases, namely carbon dioxide, methane,
nitrous oxide, ozone and chlorofluorocarbons.
(1)
11.
According to molecular orbital theory electronic configurations of O 2+ and
O 2– species are as follows :
O2 : (σ1s) (σ* 1s ) (σ2s) (σ* 2s ) (σ2pz) (π2p2x , π2p 2y) (π* 2px1 )
+
2
2
2
2
2
O2– : (σ1s) 2 (σ* 1s 2) (σ2s)2 (σ* 2s 2 ) (σ2pz) 2 (π2p2x ,π2p 2y ) (π* 2px2 , π* 2py1)
Bond order of O2 =
10 − 5
5
=
= 2.5
2
2
Bond order of O2– =
10 − 7 3
= = 1.5
2
2
+
(½ × 2)
+
no
• Higher bond order of O2 shows that its bond energy
is more than that of O2– hence it is more stable than O –2 .
(½ × 2)
• Both the species have unpaired electrons. So both
are paramagnetic in nature.
12.
Since reaction is endothermic, according to Le Chatelier’s principle,
increase of temperature will increase the value of K.
193 Model Question Paper
13.
• Use of correct formula
(½)
• Correct substitution of values
(½)
• Correct value of
(½)
• Correct interpretation
(½)
pH of HOCl = 2.85
+
But, – pH = log [H ]
+
∴ – 2.85 = log [H ]
⇒ 3 .15 = log [H ]
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+
⇒
[H+] = 1.413 × 10–3
+
For weak mono basic acid [H ] =
Ka × C
+ 2
⇒
Ka =
–3 2
[H ]
(1.413 × 10 )
=
C
0.08
–6
= 24.957 × 10 = 2.4957 × 10
+
14.
–5
• Correct calculations of [H ]
(1)
• Correct calculations of K a
(1)
PbO is basic oxide and simple acid base reaction takes place between
PbO and HNO3. On the other hand in PbO2 lead is in +4 oxidation state
and can not be oxidised further. Therefore no reaction takes place. Thus
PbO2 is passive, only PbO reacts with HNO3.
2PbO + 4HNO3 ⎯→ 2Pb (NO3)2 + 2H2O
• Correct reason
(1½)
• Chemical equation
5 volume H2O 2 solution means that hydrogen peroxide contained in
1 volume of this solution will decompose to give 5 volumes of oxygen at
STP i.e. if 1L of this solution is taken, then 5 L of oxygen can be produced
from this at STP. Chemical equation for the decomposition of H2O2 is
2H2O 2(l) ⎯→ O2(g) + H2O(l).
no
15.
(½)
It shows that 68 g H2O 2 gives 22.7 L of O2 at STP, so 5 L oxygen will be
obtained from :
68g × 5L
22 .7L
=
3400
227
g H2O 2 = 14.9 g ≈ 15 g H2O2
i.e., 15 g H2O2 dissolved in 1 L solution will give 5 L oxygen or 1.5 g
H2O2/100 mL solution will give 500 mL oxygen. Thus 15 g/L or 1.5%
solution is known as 5V solution of H2O 2.
Exemplar Problems, Chemistry 194
16.
• Correct chemical equation
(1)
• Correct Chemical formula
(½)
• Correct value
(½)
h
mv
m = 100 g = 0.1 kg.
λ=
v = 100 km/h =
10 0 × 10 00 m 1000
−1
=
ms
60 × 60 s
36
h = 6.626 × 10–34 Js
−34
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6.626 × 10 Js
− 36
−1
λ=
= 6.626 × 10 × 36 m = 238.5 × 10–36m–1
1000
0.1 kg ×
ms −1
36
Since the wavelength is very small, the wave nature cannot be detected.
• Using correct formula
(½)
• Putting correct values
• Correct answer
(½)
(½)
• Correct interpretation
(1½)
17.
The outermost electronic configuration of nitrogen 2s 2 2p1x 2p1y 2p1z is very
stable due to half filled p-orbital. Addition of extra electron to any of the
2p orbital requires energy. Oxygen has 4 electrons in 2p orbitals and
acquires stable configuration 2p 3 after removing one electron.
(3)
18.
(i)
(ii)
(Oxygen attached
with double bond,
oxygen attached
with single bond
and hydrogen atom
have zero formal
charge)
(Oxygen attached to
nitrogen with double
bond has no formal
charge)
(formal charge on
each atom is zero)
• Correct Lewis structure for each compound
(½×3)
• Showing correct formal charge on atom(s) in each structure
(½×3)
no
19.
(iii)
At constant volume
By first law of thermodynamics:
q = ΔU + (–w)
V
but (–w) = pΔV
∴ qV = ΔU + pΔV
195 Model Question Paper
ΔV = 0, since volume is constant.
∴ qV = ΔU + 0
⇒ qV = ΔU = change in internal energy
At constant pressure
q p = ΔU + pΔV
But, ΔU + pΔV = ΔH
∴ q p = ΔH = change in enthalpy.
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So, at a constant volume and at constant pressure heat change is state
function because it is equal to change in internal energy and change in
enthalpy respectively which are state functions.
20.
• Derivation for constant volume
(1)
• Derivation for constant pressure
(1)
• Correct interpretation
(1)
Let S be the solubility of Al(OH)3 in mol L–1.
Al (OH)3
Concentration of
–1
species at t = 0 in mol L
Concentration of various
species at equilibrium in
–1
mol L
Al3+ (aq) + 3OH– (aq)
U
1
0
0
1–S
S
3S
K sp= [Al3+ ] [OH– ]3 = (S) (3S)3 = 27 S4
S4 =
K sp
27
=
2.7 × 10
27
–3
− 11
–11
=
27 × 10
27 × 10
= 1 × 10–12
–1
S = 1× 10 mol L
(i)
Molar mass of Al (OH)3 is 78 g mol–1. Therefore,
–1
–3
Solubility of Al (OH)3 in g L = (1 × 10
–1
–1
mol L ) × (78 g L )
–3
–1
= 78 × 10 g L
= 7.8 × 10–2 g L–1
• Putting correct values in equation
• Correct answer
no
(ii)
(1)
(1)
pH of the solution
–3
–1
S = 1×10 mol L
[OH – ] = 3S = 3×1×10–3 = 3 × 10–3 mol L–1
pOH = 3 – log 3
pH = 14 – pOH = 11 + log 3 = 11.4771 ≈ 11.5
• Using correct formula
• Correct answer
Exemplar Problems, Chemistry 196
(½)
(½)
21.
22.
(a) +2
(i) Heavy water,
(b) +5, 0, 0, +5
(1+2)
(D2O)
[½ ×2]
(ii) No, the reactivity of both the isotopes will not be the same.
(1)
Justification: The reactivity depends upon enthalpy of bond
dissociation. Due to the difference in the enthalpy
of bond dissociation for two isotopes, the rate of
reaction will be different.
(i)
BeSO4 and MgSO4 are readily soluble in water because
greater hydration enthalpies of Be2+ and Mg2+ ions overcome
the lattice enthalpy factor.
(2)
If the temperature is raised above 393 K, plaster of paris
is further dehydrated to form anhydrous calcium sulphate.
(1)
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23.
(1)
(ii)
24.
Pt/Pd/Ni
CH3CH = CH2 + H2 ⎯⎯⎯⎯⎯
→ CH3CH2CH3
(i)
Zn, H+
CH3CH2CH2Cl + H2 ⎯⎯⎯⎯
→ CH3CH2CH3 + HCl
(ii)
CuO
CH3CH2CH2COO– Na+ + NaOH ⎯⎯⎯
CH3CH2CH3 + Na2CO3
Δ →
(iii)
• 1 mark for each part for writing correct chemical
equation for the reaction
(1×3)
(iii)
(2)
26.
(iii)
(2)
27.
(ii)
(2)
28.
(a) Suppose gas is at point ‘A’ on
isotherm T1. First increase the
temperature of the gas above
critical temperature (T c)
keeping the volume constant.
Suppose the gas reaches the
point ‘F’ on isotherm T2 where
it is at volume V1 and pressure
p1. Now compress the gas upto
Volume V2. In this compression
the pressure and volume of the
gas will move along the curve
FG (Boyle law) at point G, let
the pressure at point G be p2.
Now start cooling the gas. As
soon as gas will reach the
point ‘H’ located on isotherm
of critical temperature, it
will liquify without passing
no
25.
197 Model Question Paper
through equilibrium state. The gas will not pass through two phases
because volume (V 2) of the gas is less than critical volume i.e.
molecules are closer to each other. Gas is at a higher pressure than
critical pressure. Cooling slows down the molecular motion and
intermolecular forces can hold the molecules together.
• Correct graph with proper labelling
• Explanation
(b)
(1)
(2)
benzene < water < ethane-1, 2-diol
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Reason : Ethane-1, 2-diol has more hydogen bonding than water while
in benzene hydrogen bonding is absent.
• Correct order
• Correct reason
29.
(a)
(1)
(1)
(i) BCl3 is an electron deficient compound. In order to complete
its octet, boron has a tendency to accept a pair of electrons.
BCl3 + NH3 ⎯→ BCl3 : NH3
(1)
(ii) It is not an acid according to proton concept, However it accepts
–
–
(1)
one OH from water to form B(OH4) .
(b)
(i) A = B 2H 6; B = B2H6.2NH3; C=B3N3H6
(ii) Reactions :
B2H6 + 2NH3 ⎯→ B 2H 6.2NH3
A
(1½)
B
Δ
3B 2H 6 . 6NH3 ⎯⎯→
2.
30. (a)
+ 12H 2
Inductive effect
(1½)
Resonance effect
Involves σ-electrons
(i)
(ii)
vanishes beyond third
carbon atom
(ii) present all along the length
if system is conjugated
(iii)
Exhibited by even
non-planar compounds
(iii) Exhibited by only planar
compounds
no
(i)
• (Any two) (1 mark each)
Exemplar Problems, Chemistry 198
involves π- electrons or lone
pair of electrons
(2)
(b) Polarisation of CH3CH2Cl and CH3CH2Br can be shown as follows:
and
(½)
• Chlorine is more electronegative than bromine. Therefore C—Cl bond
is more polar than C—Br bond. Hence inductive effect is greater on
(1)
second carbon atom in CH2CH2Cl.
(c) • Resonating structures of CH3–CH=CH–CH=CH3
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(1)
• Due to resonance effect, I is more stable. There is no conjugation in
(½)
no
CH3CH = CH—(CH2)2—CH = CH2
199 Model Question Paper
Unit
1
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SOME B
ASIC CONCEP
TS
BA
CONCEPTS
OF CHEMIS
TRY
CHEMISTRY
I. Multiple Choice Questions (Type-I)
1.
Two students performed the same experiment separately and each one of
them recorded two readings of mass which are given below. Correct reading
of mass is 3.0 g. On the basis of given data, mark the correct option out of the
following statements.
Student
Readings
(i)
(ii)
A
3.01
2.99
B
3.05
2.95
(i) Results of both the students are neither accurate nor precise.
(ii) Results of student A are both precise and accurate.
(iii) Results of student B are neither precise nor accurate.
(iv) Results of student B are both precise and accurate.
A measured temperature on Fahrenheit scale is 200 °F. What will this reading
be on Celsius scale?
(i)
40 °C
(ii)
94 °C
(iii)
93.3 °C
(iv)
30 °C
no
2.
3.
What will be the molarity of a solution, which contains 5.85 g of NaCl(s) per
500 mL?
(i)
4 mol L –1
(ii)
20 mol L
–1
4.
0.2 mol L–1
(iv)
2 mol L–1
If 500 mL of a 5M solution is diluted to 1500 mL, what will be the molarity of
the solution obtained?
(i)
1.5 M
(ii)
1.66 M
(iii)
0.017 M
(iv)
1.59 M
The number of atoms present in one mole of an element is equal to Avogadro
number. Which of the following element contains the greatest number of
atoms?
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5.
(iii)
6.
7.
8.
(i)
4g He
(ii)
46g Na
(iii)
0.40g Ca
(iv)
12g He
If the concentration of glucose (C6H12O6) in blood is 0.9 g L–1, what will be the
molarity of glucose in blood?
(i)
5M
(ii)
50 M
(iii)
0.005 M
(iv)
0.5 M
What will be the molality of the solution containing 18.25 g of HCl gas in
500 g of water?
(i)
0.1 m
(ii)
1M
(iii)
0.5 m
(iv)
1m
One mole of any substance contains 6.022 × 1023 atoms/molecules. Number
of molecules of H 2SO 4 present in 100 mL of 0.02M H2SO4 solution is ______.
20
12.044 × 10
no
(i)
9.
molecules
23
(ii)
6.022 × 10 molecules
(iii)
1 × 1023 molecules
(iv)
12.044 × 10
23
molecules
What is the mass percent of carbon in carbon dioxide?
(i)
0.034%
(ii)
27.27%
Exemplar Problems, Chemistry
2
(iii)
3.4%
(iv)
28.7%
10. The empirical formula and molecular mass of a compound are CH2O and
180 g respectively. What will be the molecular formula of the compound?
(i)
C9H18O 9
(ii)
CH2O
(iii)
C6H12O 6
(iv)
C2H4O2
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11. If the density of a solution is 3.12 g mL–1, the mass of 1.5 mL solution in
significant figures is _______.
(i)
4.7g
(ii)
4680 × 10–3g
(iii)
4.680g
(iv)
46.80g
12. Which of the following statements about a compound is incorrect?
(i)
A molecule of a compound has atoms of different elements.
(ii)
A compound cannot be separated into its constituent elements by
physical methods of separation.
(iii)
A compound retains the physical properties of its constituent elements.
(iv)
The ratio of atoms of different elements in a compound is fixed.
13. Which of the following statements is correct about the reaction given below:
4Fe(s) + 3O2(g) ⎯→ 2Fe2O3(g)
Total mass of iron and oxygen in reactants = total mass of iron and
oxygen in product therefore it follows law of conservation of mass.
(ii)
Total mass of reactants = total mass of product; therefore, law of multiple
proportions is followed.
(iii)
Amount of Fe2O3 can be increased by taking any one of the reactants
(iron or oxygen) in excess.
(iv)
Amount of Fe2O3 produced will decrease if the amount of any one of the
reactants (iron or oxygen) is taken in excess.
no
(i)
14. Which of the following reactions is not correct according to the law of
conservation of mass.
(i)
2Mg(s) + O 2(g) ⎯→ 2MgO(s)
(ii)
C3H8(g) + O2(g) ⎯→ CO2(g) + H2O(g)
(iii)
P 4(s) + 5O2(g) ⎯→ P4O10(s)
(iv)
CH4(g) + 2O2(g) ⎯→ CO2(g) + 2H2O (g)
3
Some Basic Concepts of Chemistry
15. Which of the following statements indicates that law of multiple proportion is
being followed.
Sample of carbon dioxide taken from any source will always have carbon
and oxygen in the ratio 1:2.
(ii)
Carbon forms two oxides namely CO2 and CO, where masses of oxygen
which combine with fixed mass of carbon are in the simple ratio 2:1.
(iii)
When magnesium burns in oxygen, the amount of magnesium taken
for the reaction is equal to the amount of magnesium in magnesium
oxide formed.
(iv)
At constant temperature and pressure 200 mL of hydrogen will combine
with 100 mL oxygen to produce 200 mL of water vapour.
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(i)
II. Multiple Choice Questions (Type-II)
In the following questions two or more options may be correct.
16. One mole of oxygen gas at STP is equal to _______.
(i)
6.022 × 1023 molecules of oxygen
(ii)
6.022 × 1023 atoms of oxygen
(iii)
16 g of oxygen
(iv)
32 g of oxygen
17. Sulphuric acid reacts with sodium hydroxide as follows :
H 2SO4 + 2NaOH ⎯→ Na2SO4 + 2H2O
When 1L of 0.1M sulphuric acid solution is allowed to react with 1L of 0.1M
sodium hydroxide solution, the amount of sodium sulphate formed and its
molarity in the solution obtained is
(i)
0.1 mol L–1
(ii)
7.10 g
(iii)
0.025 mol L–1
(iv)
3.55 g
18. Which of the following pairs have the same number of atoms?
16 g of O2(g) and 4 g of H2(g)
(ii)
16 g of O2 and 44 g of CO2
(iii)
28 g of N2 and 32 g of O 2
(iv)
12 g of C(s) and 23 g of Na(s)
no
(i)
19. Which of the following solutions have the same concentration?
(i)
20 g of NaOH in 200 mL of solution
(ii)
0.5 mol of KCl in 200 mL of solution
Exemplar Problems, Chemistry
4
(iii)
40 g of NaOH in 100 mL of solution
(iv)
20 g of KOH in 200 mL of solution
20. 16 g of oxygen has same number of molecules as in
(i)
16 g of CO
(ii)
28 g of N2
(iii)
14 g of N2
(iv)
1.0 g of H2
21. Which of the following terms are unitless?
Molality
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(i)
(ii)
Molarity
(iii)
Mole fraction
(iv)
Mass percent
22. One of the statements of Dalton’s atomic theory is given below:
“Compounds are formed when atoms of different elements combine in a fixed
ratio”
Which of the following laws is not related to this statement?
(i)
Law of conservation of mass
(ii)
Law of definite proportions
(iii)
Law of multiple proportions
(iv)
Avogadro law
III. Short Answer Type
23. What will be the mass of one atom of C-12 in grams?
24. How many significant figures should be present in the answer of the following
calculations?
2.5 × 1.25 × 3.5
2.01
25. What is the symbol for SI unit of mole? How is the mole defined?
no
26. What is the difference between molality and molarity?
27. Calculate the mass percent of calcium, phosphorus and oxygen in calcium
phosphate Ca3(PO4)2.
28. 45.4 L of dinitrogen reacted with 22.7 L of dioxygen and 45.4 L of nitrous
oxide was formed. The reaction is given below:
2N2(g) +
O2(g)
⎯→
2N2O(g)
Which law is being obeyed in this experiment? Write the statement of the law?
5
Some Basic Concepts of Chemistry
29. If two elements can combine to form more than one compound, the masses of
one element that combine with a fixed mass of the other element, are in whole
number ratio.
(a)
Is this statement true?
(b)
If yes, according to which law?
(c)
Give one example related to this law.
30. Calculate the average atomic mass of hydrogen using the following data :
% Natural abundance
Molar mass
1
H
99.985
1
2
H
0.015
2
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Isotope
31. Hydrogen gas is prepared in the laboratory by reacting dilute HCl with
granulated zinc. Following reaction takes place.
Zn + 2HCl ⎯→ ZnCl 2 + H2
Calculate the volume of hydrogen gas liberated at STP when 32.65 g of zinc
reacts with HCl. 1 mol of a gas occupies 22.7 L volume at STP; atomic mass of
Zn = 65.3 u.
32. The density of 3 molal solution of NaOH is 1.110 g mL–1. Calculate the molarity
of the solution.
33. Volume of a solution changes with change in temperature, then, will the molality
of the solution be affected by temperature? Give reason for your answer.
34. If 4 g of NaOH dissolves in 36 g of H 2O, calculate the mole fraction of each
component in the solution. Also, determine the molarity of solution (specific
–1
gravity of solution is 1g mL ).
35. The reactant which is entirely consumed in reaction is known as limiting reagent.
In the reaction 2A + 4B → 3C + 4D, when 5 moles of A react with 6 moles of B,
then
(i)
which is the limiting reagent?
(ii)
calculate the amount of C formed?
no
IV. Matching Type
36. Match the following:
(i)
88 g of CO2
(a)
0.25 mol
(ii)
23
6.022 ×10 molecules of H2O
(b)
2 mol
(iii)
5.6 litres of O2 at STP
(c)
1 mol
(iv)
96 g of O2
(d)
6.022 × 1023 molecules
(v)
1 mol of any gas
(e)
3 mol
Exemplar Problems, Chemistry
6
37. Match the following physical quantities with units
Physical quantity
Unit
–1
Molarity
(a)
g mL
(ii)
Mole fraction
(b)
mol
(iii)
Mole
(c)
Pascal
(iv)
Molality
(d)
Unitless
(v)
Pressure
(e)
mol L–1
(vi)
Luminous intensity
(f)
Candela
(vii)
Density
(g)
mol kg–1
(viii)
Mass
(h)
Nm–1
(i)
kg
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(i)
V. Assertion and Reason Type
In the following questions a statement of Assertion (A) followed by a
statement of Reason (R) is given. Choose the correct option out of the
choices given below each question.
38. Assertion (A) : The empirical mass of ethene is half of its molecular mass.
Reason (R) :
The empirical formula represents the simplest whole number
ratio of various atoms present in a compound.
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
A is true but R is false.
(iii)
A is false but R is true.
(iv)
Both A and R are false.
39. Assertion (A) : One atomic mass unit is defined as one twelfth of the mass of
one carbon-12 atom.
Reason (R) :
Carbon-12 isotope is the most abundunt isotope of carbon
and has been chosen as standard.
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
no
(i)
(iv)
Both A and R are false.
40. Assertion (A) : Significant figures for 0.200 is 3 where as for 200 it is 1.
Reason (R) :
Zero at the end or right of a number are significant provided
they are not on the right side of the decimal point.
(i)
Both A and R are true and R is correct explanation of A.
(ii)
Both A and R are true but R is not a correct explanation of A.
7
Some Basic Concepts of Chemistry
(iii)
A is true but R is false.
(iv)
Both A and R are false.
41. Assertion (A) : Combustion of 16 g of methane gives 18 g of water.
Reason (R) : In the combustion of methane, water is one of the products.
Both A and R are true but R is not the correct explanation of A.
(ii)
A is true but R is false.
(iii)
A is false but R is true.
(iv)
Both A and R are false.
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(i)
VI. Long Answer Type
42. A vessel contains 1.6 g of dioxygen at STP (273.15K, 1 atm pressure). The
gas is now transferred to another vessel at constant temperature, where
pressure becomes half of the original pressure. Calculate
(i)
volume of the new vessel.
(ii)
number of molecules of dioxygen.
43. Calcium carbonate reacts with aqueous HCl to give CaCl 2 and CO 2 according
to the reaction given below:
CaCO3 (s) + 2HCl (aq) ⎯→ CaCl2(aq) + CO2(g) + H2O(l)
What mass of CaCl 2 will be formed when 250 mL of 0.76 M HCl reacts with
1000 g of CaCO 3? Name the limiting reagent. Calculate the number of moles
of CaCl 2 formed in the reaction.
44. Define the law of multiple proportions. Explain it with two examples. How
does this law point to the existance of atoms?
no
45. A box contains some identical red coloured balls, labelled as A, each weighing
2 grams. Another box contains identical blue coloured balls, labelled as B,
each weighing 5 grams. Consider the combinations AB, AB2, A2B and A2B3
and show that law of multiple proportions is applicable.
Exemplar Problems, Chemistry
8
ANSWERS
I. Multiple Choice Questions (Type-I)
1. (ii)
2. (iii)
3. (iii)
4. (ii)
5. (iv)
6. (iii)
7. (iv)
8. (i)
9. (ii)
10. (iii)
11. (i)
12. (iii)
13. (i)
14. (ii)
15. (ii)
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II. Multiple Choice Questions (Type-II)
16. (i), (iv)
17. (ii), (iii)
18. (iii), (iv)
19. (i), (ii)
20. (iii), (iv)
21. (iii), (iv)
22. (i), (iv)
III. Short Answer Type
23.
1.992648 × 10–23 g ≈ 1.99 × 10–23 g
24.
2
25.
Symbol for SI Unit of mole is mol.
One mole is defined as the amount of a substance that contains as many
particles or entities as there are atoms in exactly 12 g (0.012 kg) of the 12C
isotope.
26.
Molality is the number of moles of solute present in one kilogram of solvent
but molarity is the number of moles of solute dissolved in one litre of
solution.
Molality is independent of temperature whereas molarity depends on
temperature.
Mass percent of calcium =
no
27.
=
Mass percent of phosphorus =
=
3 × (atomic mass of calcium)
×100
molecular mass of Ca 3 (PO4 )2
120 u
×100 = 38.71%
310 u
2 × (atomic mass of phosphorus)
× 100
molecular mass of Ca3 (PO4 )2
2 × 31 u
×100 = 20%
310 u
9
Some Basic Concepts of Chemistry
8 × (Atomic mass of oxygen)
Mass percent of oxygen = molecular mass of Ca (PO ) × 100
3
4 2
=
8 × 16 u
×100 = 41.29%
310 u
28.
According to Gay Lussac’s law of gaseous volumes, gases combine or are
produced in a chemical reaction in a simple ratio by volume, provided
that all gases are at the same temperature and pressure.
29.
(a)
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Yes
(b)
(c)
According to the law of multiple proportions
H2
+
2g
(c)
H2
→
O2
H2O
16 g
+
2g
18 g
→
O2
H2O2
32 g
34 g
Here masses of oxygen, (i.e., 16 g in H2O and 32 g in H2O 2) which combine
with fixed mass of hydrogen (2 g) are in the simple ratio i.e., 16 : 32 or 1 : 2
1
30.
31.
{(Natural abundance of H × molar mass) +
2
2
(Natural abundance of H × molar mass of H)}
Average Atomic Mass =
100
=
99.985 × 1 + 0.015 × 2
100
=
99.985 + 0.030
1 0 0 .0 15
=
= 1.00015 u
100
100
From the equation, 63.5 g of zinc liberates 22.7 litre of hydrogen. So
32.65 g of zinc will liberate
22.7 L H2
65.3 g Zn
=
22.7
L = 11.35 L
2
no
32.65 g Zn ×
32.
3 molal solution of NaOH means that 3 mols of NaOH are dissolved in
1000 g of solvent.
∴ Mass of Solution = Mass of Solvent + Mass of Solute
= 1000 g + (3 × 40 g) = 1120 g
Volume of Solution =
Exemplar Problems, Chemistry
10
1120
mL = 1009.00 mL
1.110
(Since density of solution = 1.110g mL–1)
Since 1009 mL solution contains 3 mols of NaOH
∴ Molarity =
=
3 mol
× 1000 = 2.97 M
1009.00
No, Molality of solution does not change with temperature since mass
remains unaffected with temperature.
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33.
Number of moles of solute
Volume of solution in litre
34.
Mass of NaOH = 4 g
Number of moles of NaOH =
4 g
= 0.1 mol
40 g
Mass of H2O = 36 g
Number of moles of H2O =
Mole fraction of water =
=
Mole fraction of NaOH =
=
36 g
= 2 mol
18 g
Number of moles of H2O
No. of moles of water + No. of moles of NaOH
2
2
=
= 0.95
2 + 0.1 2.1
Number of moles of NaOH
No. of moles of Na OH + No. of moles of water
0.1
0.1
=
= 0.047
2 + 0.1 2.1
Mass of solution = mass of water + mass of NaOH = 36 g + 4 g = 40 g
Volume of solution = 40 × 1 = 40 mL
–1
(Since specific gravity of solution is = 1 g mL )
no
Molarity of solution =
35.
=
Number of moles of solute
Volume of solution in litre
0.1 mol NaOH
= 2.5 M
0.04 L
2A + 4B → 3C + 4D
According to the above equation, 2 mols of ‘A’ require 4 mols of ‘B’ for the
reaction.
11 Some Basic Concepts of Chemistry
Hence, for 5 mols of ‘A’, the moles of ‘B’ required = 5 mol of A ×
4 mol of B
2 mol of A
= 10 mol B
But we have only 6 mols of ‘B’, hence, ‘B’ is the limiting reagent. So amount
of ‘C’ formed is determined by amount of ‘B’.
Since 4 mols of ‘B’ give 3 mols of ‘C’. Hence 6 mols of ‘B’ will give
3 mol of C
= 4.5 mol of C
4 mol of B
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6 mol of B ×
IV. Matching Type
36.
(i) → (b)
(ii) → (c)
(iii) → (a)
(iv) → (e)
(i) → (e)
(ii) → (d)
(iii) → (b)
(iv) → (g)
(v) → (c), (h)
(vi) → (f)
(vii) → (a)
(viii) → (i)
(v) → (d)
37.
V. Assertion and Reason Type
38. (i)
39. (ii)
40. (iii)
41. (iii)
VI. Long Answer Type
42.
(i) p 1=1 atm,
T1=273 K,
V1=?
32 g of oxygen occupies 22.4 L of volume at STP*
Hence, 1.6 g of oxygen will occupy, 1.6 g oxygen ×
22.4 L
= 1.12 L
32 g oxygen
V 1=1.12 L
no
p2 =
1
= = 0.5 atm.
2 2
V 2=?
According to Boyle’s law :
p 1V1 = p2V2
V2 =
*
p1
p1× V1
p2
=
1 atm. × 1.12 L
= 2.24 L
0.5 atm.
Old STP conditions 273.15 K, 1 atm, volume occupied by 1 mol of gas = 22.4 L.
New STP conditions 273.15 K, 1 bar, volume occupied by a gas = 22.7 L.
Exemplar Problems, Chemistry
12
6.022 × 10
(ii) Number of molecules of oxygen in the vessel =
32
23
× 1.6
= 3.011 × 1022
43.
Number of moles of HCl = 250 mL ×
0.76 M
= 0.19 mol
1000
Mass of CaCO3 = 1000 g
Number of moles of CaCO 3 =
1000 g
= 10 mol
100 g
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According to given equation 1 mol of CaCO 3 (s) requires 2 mol of HCl (aq).
Hence, for the reaction of 10 mol of CaCO3 (s) number of moles of HCl
required would be:
10 mol CaCO 3 ×
2 mol HCl (a q)
1 mol CaCO 3 (s) = 20 mol HCl (aq)
But we have only 0.19 mol HCl (aq), hence, HCl (aq) is limiting reagent.
So amount of CaCl2 formed will depend on the amount of HCl available.
Since, 2 mol HCl (aq) forms 1 mol of CaCl2, therefore, 0.19 mol of HCl (aq)
would give:
0.19 mol HCl (aq) ×
or
2 mol HCl (aq)
= 0.095 mol
0.095 × molar mass of CaCl2 = 0.095 × 111 = 10.54 g
(Hint : Show that the masses of B which combine with the fixed mass of
A in different combinations are related to each other by simple whole
numbers).
no
45.
1 mol CaCl2 (aq)
13 Some Basic Concepts of Chemistry
Unit
2
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STRUC
TURE OF A
TOM
TRUCTURE
AT
I. Multiple Choice Questions (Type-I)
1.
2.
(i)
(ii)
Most of the space in the atom is empty.
The radius of the atom is about 10–10 m while that of nucleus is 10 –15 m.
(iii)
(iv)
Electrons move in a circular path of fixed energy called orbits.
Electrons and the nucleus are held together by electrostatic forces of
attraction.
Which of the following options does not represent ground state electronic
configuration of an atom?
(i)
(ii)
1s 2 2s 2 2p6 3s2 3p6 3d8 4s 2
1s 2 2s 2 2p6 3s2 3p6 3d9 4s 2
(iii)
1s 2 2s 2 2p6 3s2 3p6 3d10 4s 1
(iv)
1s 2 2s 2 2p6 3s2 3p6 3d5 4s 1
The probability density plots of 1s and 2s orbitals are given in Fig. 2.1:
no
3.
Which of the following conclusions could not be derived from Rutherford’s
α -particle scattering experiement?
1s
2s
Fig. 2.1
The density of dots in a region represents the probability density of finding
electrons in the region.
On the basis of above diagram which of the following statements is incorrect?
5.
6.
(ii)
The probability of finding the electron is maximum near the nucleus.
(iii)
The probability of finding the electron at a given distance is equal in all
directions.
(iv)
The probability density of electrons for 2s orbital decreases uniformly
as distance from the nucleus increases.
Which of the following statement is not correct about the characteristics of
cathode rays?
(i)
They start from the cathode and move towards the anode.
(ii)
They travel in straight line in the absence of an external electrical or
magnetic field.
(iii)
Characteristics of cathode rays do not depend upon the material of
electrodes in cathode ray tube.
(iv)
Characteristics of cathode rays depend upon the nature of gas present
in the cathode ray tube.
Which of the following statements about the electron is incorrect?
(i)
It is a negatively charged particle.
(ii)
The mass of electron is equal to the mass of neutron.
(iii)
It is a basic constituent of all atoms.
(iv)
It is a constituent of cathode rays.
Which of the following properties of atom could be explained correctly by
Thomson Model of atom?
(i)
Overall neutrality of atom.
(ii)
Spectra of hydrogen atom.
(iii)
Position of electrons, protons and neutrons in atom.
(iv)
Stability of atom.
Two atoms are said to be isobars if.
(i)
they have same atomic number but different mass number.
(ii)
they have same number of electrons but different number of neutrons.
(iii)
they have same number of neutrons but different number of electrons.
(iv)
sum of the number of protons and neutrons is same but the number of
protons is different.
no
7.
1s and 2s orbitals are spherical in shape.
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4.
(i)
8.
The number of radial nodes for 3p orbital is __________.
(i)
3
(ii)
4
(iii)
2
(iv)
1
15 Structure of Atom
9. Number of angular nodes for 4d orbital is __________.
(i)
4
(ii)
3
(iii)
2
(iv)
1
10. Which of the following is responsible to rule out the existence of definite paths
or trajectories of electrons?
Pauli’s exclusion principle.
(ii)
Heisenberg’s uncertainty principle.
(iii)
Hund’s rule of maximum multiplicity.
(iv)
Aufbau principle.
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(i)
11. Total number of orbitals associated with third shell will be __________.
(i)
2
(ii)
4
(iii)
9
(iv)
3
12. Orbital angular momentum depends on __________.
(i)
l
(ii)
n and l
(iii)
n and m
(iv)
m and s
13. Chlorine exists in two isotopic forms, Cl-37 and Cl-35 but its atomic mass is
35.5. This indicates the ratio of Cl-37 and Cl-35 is approximately
(i)
1:2
(ii)
1:1
(iii)
1:3
(iv)
3:1
14. The pair of ions having same electronic configuration is __________.
Cr3+, Fe3+
(ii)
Fe3+, Mn 2+
(iii)
Fe3+, Co3+
(iv)
Sc3+, Cr3+
no
(i)
15. For the electrons of oxygen atom, which of the following statements is correct?
(i)
Zeff for an electron in a 2s orbital is the same as Zeff for an electron in a 2p
orbital.
(ii)
An electron in the 2s orbital has the same energy as an electron in the
2p orbital.
Exemplar Problems, Chemistry
16
(iii)
Zeff for an electron in 1s orbital is the same as Zeff for an electron in a 2s
orbital.
(iv)
The two electrons present in the 2s orbital have spin quantum numbers
ms but of opposite sign.
16. If travelling at same speeds, which of the following matter waves have the
shortest wavelength?
Electron
(ii)
Alpha particle (He2+ )
(iii)
Neutron
(iv)
Proton
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(i)
II. Multiple Choice Questions (Type-II)
In the following questions two or more options may be correct.
17. Identify the pairs which are not of isotopes?
(i)
12
(ii)
35
(iii)
14
(iv)
8
6
17
6
4
X,
13
X,
37
X,
14
X,
6
17
7
8
5
Y
Y
Y
Y
18. Out of the following pairs of electrons, identify the pairs of electrons present
in degenerate orbitals :
(i)
n = 3, l = 2,
ml = –2, ms = −
1
2
(b)
n = 3, l = 2,
ml = –1, ms = −
1
2
(a)
n = 3, l = 1,
ml = 1,
ms = +
1
2
no
(ii)
(a)
(iii)
(b)
n = 3, l = 2,
ml = 1,
ms = +
1
2
(a)
n = 4, l = 1,
ml = 1,
ms = +
1
2
(b)
n = 3, l = 2,
ml = 1,
ms = +
1
2
17 Structure of Atom
(iv)
(a)
n = 3, l = 2,
m l = +2, ms = −
1
2
(b)
n = 3, l = 2,
m l = +2, ms = +
1
2
19. Which of the following sets of quantum numbers are correct?
l
ml
(i)
1
1
+2
(ii)
2
1
+1
(iii)
3
2
–2
(iv)
3
4
–2
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n
20. In which of the following pairs, the ions are iso-electronic?
(i)
Na+ , Mg2+
(ii)
Al3+ , O–
(iii)
Na+ , O2–
(iv)
N3–, Cl–
21. Which of the following statements concerning the quantum numbers are
correct?
(i)
Angular quantum number determines the three dimensional shape of
the orbital.
(ii)
The principal quantum number determines the orientation and energy
of the orbital.
(iii)
Magnetic quantum number determines the size of the orbital.
(iv)
Spin quantum number of an electron determines the orientation of the
spin of electron relative to the chosen axis.
III. Short Answer Type
22. Arrange s, p and d sub-shells of a shell in the increasing order of effective
nuclear charge (Zeff) experienced by the electron present in them.
no
23. Show the distribution of electrons in oxygen atom (atomic number 8) using
orbital diagram.
24. Nickel atom can lose two electrons to form Ni2+ ion. The atomic number of
nickel is 28. From which orbital will nickel lose two electrons.
25. Which of the following orbitals are degenerate?
3dxy ,4dx y 3d 2 ,3dyz ,4dyz ,4d
z
Exemplar Problems, Chemistry
18
2
z
26. Calculate the total number of angular nodes and radial nodes present in 3p
orbital.
27. The arrangement of orbitals on the basis of energy is based upon their (n+l )
value. Lower the value of (n+l ), lower is the energy. For orbitals having same
values of (n+l ), the orbital with lower value of n will have lower energy.
I.
Based upon the above information, arrange the following orbitals in the
increasing order of energy.
(a) 1s, 2s, 3s, 2p
(b) 4s, 3s, 3p, 4d
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(c) 5p, 4d, 5d, 4f, 6s
(d) 5f, 6d, 7s, 7p
II. Based upon the above information, solve the questions given below :
(a)
Which of the following orbitals has the lowest energy?
4d, 4f, 5s, 5p
(b)
Which of the following orbitals has the highest energy?
5p, 5d, 5f, 6s, 6p
28. Which of the following will not show deflection from the path on passing
through an electric field?
Proton, cathode rays, electron, neutron.
29. An atom having atomic mass number 13 has 7 neutrons. What is the atomic
number of the atom?
30. Wavelengths of different radiations are given below :
λ(A) = 300 nm
λ(B) = 300 μm
λ (C) = 3 nm
λ(D) = 30 A
0
Arrange these radiations in the increasing order of their energies.
31. The electronic configuration of valence shell of Cu is 3d104s1 and not 3d 94s 2.
How is this configuration explained?
32. The Balmer series in the hydrogen spectrum corresponds to the transition
from n 1 = 2 to n 2 = 3,4,......... . This series lies in the visible region. Calculate
no
the wave number of line associated with the transition in Balmer series when
the electron moves to n = 4 orbit.
(RH = 109677 cm–1)
33. According to de Broglie, matter should exhibit dual behaviour, that is both
particle and wave like properties. However, a cricket ball of mass 100 g does
not move like a wave when it is thrown by a bowler at a speed of 100 km/h.
Calculate the wavelength of the ball and explain why it does not show wave
nature.
19 Structure of Atom
34. What is the experimental evidence in support of the idea that electronic energies
in an atom are quantized?
35. Out of electron and proton which one will have, a higher velocity to produce
matter waves of the same wavelength? Explain it.
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36. A hypothetical electromagnetic wave is shown in Fig. 2.2. Find out the
wavelength of the radiation.
Fig. 2.2
37. Chlorophyll present in green leaves of plants absorbs light at 4.620 × 1014 Hz.
Calculate the wavelength of radiation in nanometer. Which part of the
electromagnetic spectrum does it belong to?
38. What is the difference between the terms orbit and orbital?
39. Table-tennis ball has a mass 10 g and a speed of 90 m/s. If speed can be
measured within an accuracy of 4% what will be the uncertainty in speed
and position?
40. The effect of uncertainty principle is significant only for motion of microscopic
particles and is negligible for the macroscopic particles. Justify the statement
with the help of a suitable example.
41. Hydrogen atom has only one electron, so mutual repulsion between electrons
is absent. However, in multielectron atoms mutual repulsion between the
electrons is significant. How does this affect the energy of an electron in the
orbitals of the same principal quantum number in multielectron atoms?
IV. Matching Type
no
In some of the following questions, one option of left column may be
correlated to more than one option in the right column.
42. Match the following species with their corresponding ground state electronic
configuration.
Atom / Ion
Electronic configuration
(i)
Cu
(a)
1s 2 2s 2 2p6 3s 2 3p6 3d10
(ii)
Cu2+
(b)
1s 2 2s 2 2p6 3s 2 3p 6 3d10 4s 2
Exemplar Problems, Chemistry
20
(iii)
Zn2+
(c)
1s2 2s 2 2p 6 3s 2 3p6 3d10 4s1
(iv)
Cr3+
(d)
1s2 2s2 2p6 3s 2 3p6 3d9
(e)
1s2 2s2 2p6 3s 2 3p6 3d3
43. Match the quantum numbers with the information provided by these.
Quantum number
Information provided
Principal quantum number
(a) orientation of the orbital
(ii)
Azimuthal quantum number
(b) energy and size of orbital
(iii)
Magnetic quantum number
(c) spin of electron
(iv)
Spin quantum number
(d) shape of the orbital
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(i)
44. Match the following rules with their statements :
Statements
Rules
(i)
Hund’s Rule
(ii)
Aufbau Principle
(iii)
Pauli Exclusion Principle
(iv)
Heisenberg’s Uncertainty
Principle
(a)
No two electrons in an atom
can have the same set of four
quantum numbers.
(b)
Half-filled and completely filled
orbitals have extra stablity.
(c)
Pairing of electrons in the
orbitals belonging to the same
subshell does not take place
until each orbital is singly
occupied.
(d)
It is impossible to determine
the exact position and exact
momentum of a subatomic
particle simultaneously.
(e)
In the ground state of atoms,
orbitals are filled in the order
of their increasing energies.
45. Match the following
X-rays
no
(i)
(a) ν = 10 0 – 104 Hz
(ii)
UV
(b) ν = 1010 Hz
(iii)
Long radio waves
(c) ν = 1016 Hz
(iv)
Microwave
(d) ν = 1018 Hz
21 Structure of Atom
46. Match the following
(i)
Photon
(a) Value is 4 for N shell
(ii)
Electron
(b) Probability density
(iii)
ψ
(c) Always positive value
(iv)
Principal quantum number n
2
(d) Exhibits both momentum and
wavelength
47. Match species given in Column I with the electronic configuration given in Column II.
Column II
(a) [Ar]3d84s 0
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Column I
(i)
Cr
(ii)
Fe2+
(b) [Ar]3d104s 1
(iii)
Ni2+
(c)
(iv)
Cu
(d) [Ar] 3d54s 1
(e)
[Ar]3d64s 0
[Ar]3d64s 2
V. Assertion and Reason Type
In the following questions a statement of Assertion (A) followed by a statement
of Reason (R) is given. Choose the correct option out of the choices given
below each question.
48. Assertion (A) : All isotopes of a given element show the same type of chemical
behaviour.
Reason (R) :
The chemical properties of an atom are controlled by the
number of electrons in the atom.
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
Both A and R are false.
no
49. Assertion (A) : Black body is an ideal body that emits and absorbs radiations
of all frequencies.
Reason (R) :
The frequency of radiation emitted by a body goes from a lower
frequency to higher frequency with an increase in
temperature.
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the explanation of A.
(iii)
A is true and R is false.
(iv)
Both A and R are false.
Exemplar Problems, Chemistry
22
50. Assertion (A) : It is impossible to determine the exact position and exact
momentum of an electron simultaneously.
Reason (R) :
The path of an electron in an atom is clearly defined.
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true and R is not the correct explanation of A.
(iii)
A is true and R is false.
(iv)
Both A and R are false.
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VI. Long Answer Type
51. What is photoelectric effect? State the result of photoelectric effect experiment
that could not be explained on the basis of laws of classical physics. Explain
this effect on the basis of quantum theory of electromagnetic radiations.
52. Threshold frequency, ν0 is the minimum frequency which a photon must
possess to eject an electron from a metal. It is different for different metals.
When a photon of frequency 1.0×1015 s–1 was allowed to hit a metal surface,
an electron having 1.988 × 10–19 J of kinetic energy was emitted. Calculate
the threshold frequency of this metal. Show that an electron will not be emitted
if a photon with a wavelength equal to 600 nm hits the metal surface.
53. When an electric discharge is passed through hydrogen gas, the hydrogen
molecules dissociate to produce excited hydrogen atoms. These excited atoms
emit electromagnetic radiation of discrete frequencies which can be given by
the general formula
⎡1
1 ⎤
⎥
−
2
n 2f ⎥⎦
⎢⎣n i
ν = 109677 ⎢
What points of Bohr’s model of an atom can be used to arrive at this formula?
Based on these points derive the above formula giving description of each
step and each term.
54. Calculate the energy and frequency of the radiation emitted when an electron
jumps from n = 3 to n = 2 in a hydrogen atom.
no
55. Why was a change in the Bohr Model of atom required? Due to which important
development (s), concept of movement of an electron in an orbit was replaced
by, the concept of probability of finding electron in an orbital? What is the
name given to the changed model of atom?
23 Structure of Atom
ANSWERS
I. Multiple Choice Questions (Type-I)
1. (iii)
2. (ii)
3. (iv)
4. (iv)
5. (ii)
7. (iv)
8. (iv)
9. (iii)
10. (ii)
11. (iii)
13. (iii)
14. (ii)
15. (iv)
16. (ii)
6. (i)
12. (i)
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II. Multiple Choice Questions (Type-II)
17. (iii), (iv)
18. (i), (iv)
20. (i), (iii)
21. (i), (iv)
19. (ii), (iii)
III. Short Answer Type
22. d < p < s
23.
24.
4s
25.
3dxy, 3d 2 , 3dyz and 4dxy , 4dyz, 4d
26.
For 3p orbital n = 3, l = 1
z
2
z
Number of angular nodes = l = 1
Number of radial nodes = n – l – 1 = 3–1–1=1
27.
I.
(a) Is < 2s < 2p < 3s
(b) 3s < 3p < 4s < 4d
(c) 4d < 5p < 6s < 4f < 5d
(d) 7s < 5f < 6d < 7p
neutron
no
28.
29.
A = 13, A – Z = 7 ∴ Z = 6
atomic number = 6
30.
B<A<C=D
1⎞
⎛
⎜⎝ Hint : E α ⎟⎠
λ
Exemplar Problems, Chemistry
24
II. (a) 5s (b) 5f
31.
32.
Completely filled and half filled orbitals have extra stability. In 3d104s1, d
orbital is completely filled and s is half filled. So it is more stable
configuration.
⎡1
1 ⎤
−1
2 ⎥ cm
⎢⎣ n i n f ⎥⎦
For n i = 2 to nf = 4 transition in Balmer series.
ν = 109677 ⎢
ν = 109677 ⎛⎜
∴
2
1
⎝2
−
1 ⎞
−1
2 ⎟ cm
4 ⎠
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d
2
−
⎛1 1 ⎞
−1
= 109677 ⎜ −
cm = 20564.44 cm–1
⎝ 4 16 ⎟⎠
33.
λ=
h
mv
m = 100 g = 0.1 kg.
v = 100 km/hr =
100 × 1000 m 1000
−1
=
ms
60 × 60 s
36
h = 6.626 × 10–34 Js
λ=
−34
6.626 × 10 Js
= 6.626 × 10− 36 × 36 m −1 = 238.5 × 10–36m–1
1000
−1
0.1 kg ×
ms
36
Since the wavelength is very small, the wave nature cannot be detected.
35.
Being lighter particles, electrons will have higher velocity.
h ⎞
⎛
Hint : ⎜⎝ λ =
⎟
m v⎠
36.
Wavelength is the distance between two successive peaks or two successive
troughs of a wave. So λ = 4 × 2.16 pm = 8.64 pm
λ =
c
ν
8
=
–1
3.0 × 10 ms
= 0.6494 × 10 –6 m = 649.4 nm; Visible light.
14
4.620 × 10 Hz
no
37.
39.
Uncertainty in the speed of ball =
90 × 4 360
=
= 3.6 ms –1
100
100
h
Uncertainty in position = 4π mΔ v
25 Structure of Atom
=
6.626 × 10
–34
Js
4 × 3.14 × 10 × 10 kg g × 3.6 ms
–3
–1
–1
= 1.46 × 10–33 m
41.
The energy of electron is determined by the value of n in hydrogen atom
and by n + l in multielectron atom. So for a given principal quantum
number electrons of s, p, d and f orbitals have different energy.
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IV. Matching Type
42.
(i) → (c)
(ii) → (d)
(iii) → (a)
(iv) → (e)
43.
(i) → (b)
(ii) → (d)
(iii) → (a)
(iv) → (c)
44.
(i) → (c)
(ii) → (e)
(iii) → (a)
(iv) → (d)
45.
(i) → (d)
(ii) → (c)
(iii) → (a)
(iv) → (b)
46.
(i) → (d)
(ii) → (d)
(iii) → (b), (c)
(iv) → (a), (c)
47.
(i) → (d)
(ii) → (c)
(iii) → (a)
(iv) → (b)
V. Assertion and Reason Type
48. (i)
49. (ii)
50. (iii)
VI. Long Answer Type
1
⎛
2⎞
⎜⎝ Hint : h ν = h ν 0 + mv ⎟⎠
2
54.
ΔE = –3.052 × 10–19 J, ν = 4.606 × 1016 Hz
no
52.
Exemplar Problems, Chemistry
26
Unit
3
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Classification ooff Element
Elementss
and PPeriodicit
eriodicit
y in PPrroper
ties
eriodicity
operties
I. Multiple Choice Questions (Type-I)
1.
2.
–
2–
2–
2+
+
(i)
F- < O
(ii)
Mg
(iii)
O 2– < F– < Na+ < Mg2+
(iv)
O
2–
2+
< Mg < Na
+
–
< Na < F < O
–
2+
2–
+
< F < Mg < Na
Which of the following is not an actinoid?
(i)
Curium (Z = 96)
(ii)
Californium (Z = 98)
(iii)
Uranium (Z = 92)
(iv)
Terbium (Z = 65)
The order of screening effect of electrons of s, p, d and f orbitals of a given
shell of an atom on its outer shell electrons is:
(i)
s >p > d>f
(ii)
f>d >p>s
(iii)
p<d < s >f
(iv)
f>p >s>d
no
3.
2+
Consider the isoelectronic species, Na+ , Mg , F and O . The correct order of
increasing length of their radii is _________.
4.
The first ionisation enthalpies of Na, Mg, Al and Si are in the order:
(i)
Na < Mg > Al < Si
(ii)
Na > Mg > Al > Si
5.
Na < Mg < Al < Si
(iv)
Na > Mg > Al < Si
The electronic configuration of gadolinium (Atomic number 64) is
3
5d 5 6s 2
(i)
[Xe] 4f
(ii)
[Xe] 4f 5d 6s
(iii)
[Xe] 4f 7 5d1 6s 2
(iv)
[Xe] 4f 5d 6s
7
2
8
6
1
2
The statement that is not correct for periodic classification of elements is:
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6.
(iii)
7.
(i)
The properties of elements are periodic function of their atomic numbers.
(ii)
Non metallic elements are less in number than metallic elements.
(iii)
For transition elements, the 3d-orbitals are filled with electrons after
3p-orbitals and before 4s-orbitals.
(iv)
The first ionisation enthalpies of elements generally increase with
increase in atomic number as we go along a period.
Among halogens, the correct order of amount of energy released in electron
gain (electron gain enthalpy) is:
(i)
F > Cl > Br > I
(ii)
F < Cl < Br < I
(iii)
F < Cl > Br > I
(iv)
F < Cl < Br < I
8. The period number in the long form of the periodic table is equal to
(i)
magnetic quantum number of any element of the period.
(ii)
atomic number of any element of the period.
(iii)
maximum Principal quantum number of any element of the period.
(iv)
maximum Azimuthal quantum number of any element of the period.
9. The elements in which electrons are progressively filled in 4f-orbital are called
actinoids
(ii)
transition elements
(iii)
lanthanoids
(iv)
halogens
no
(i)
10. Which of the following is the correct order of size of the given species:
–
+
(i)
I >I > I
(ii)
I+ > I– > I
(iii)
I>I >I
(iv)
I– > I > I +
+
–
Exemplar Problems, Chemistry
28
11. The formation of the oxide ion, O2– (g), from oxygen atom requires first an
exothermic and then an endothermic step as shown below:
V
O (g) + e– ⎯→ O – (g) ; Δ H = – 141 kJ mol
–1
O – (g) + e – ⎯→ O 2– (g); Δ HV = + 780 kJ mol–1
2–
Thus process of formation of O in gas phase is unfavourable even though
O 2– is isoelectronic with neon. It is due to the fact that,
oxygen is more electronegative.
(ii)
addition of electron in oxygen results in larger size of the ion.
(iii)
electron repulsion outweighs the stability gained by achieving noble
gas configuration.
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(i)
(iv)
O – ion has comparatively smaller size than oxygen atom.
12. Comprehension given below is followed by some multiple choice questions.
Each question has one correct option. Choose the correct option.
In the modern periodic table, elements are arranged in order of increasing
atomic numbers which is related to the electronic configuration. Depending
upon the type of orbitals receiving the last electron, the elements in the periodic
table have been divided into four blocks, viz, s, p, d and f. The modern periodic
table consists of 7 periods and 18 groups. Each period begins with the filling
of a new energy shell. In accordance with the Arfbau principle, the seven
periods (1 to 7) have 2, 8, 8, 18, 18, 32 and 32 elements respectively. The
seventh period is still incomplete. To avoid the periodic table being too long,
the two series of f-block elements, called lanthanoids and actinoids are placed
at the bottom of the main body of the periodic table.
(a)
(i)
s-block
(ii)
p-block
(iii)
d-block
(iv)
f-block
The last element of the p-block in 6th period is represented by the
outermost electronic configuration.
(i)
7s 2 7p 6
(ii)
5f 14 6d 10 7s 2 7p 0
(iii)
4f 14 5d 10 6s 2 6p 6
no
(b)
The element with atomic number 57 belongs to
(iv)
(c)
4f 14 5d10 6s 2 6p 4
Which of the elements whose atomic numbers are given below, cannot
be accommodated in the present set up of the long form of the periodic
table?
(i)
107
(ii)
118
29
Classification of Elements and Periodicity in Properties
(d)
126
(iv)
102
The electronic configuration of the element which is just above the
element with atomic number 43 in the same group is ________.
(i)
1s 2 2s2 2p6 3s 2 3p6 3d 5 4s2
(ii)
1s 2 2s2 2p6 3s 2 3p 6 3d 5 4s 3 4p6
(iii)
1s 2 2s2 2p6 3s 2 3p 6 3d 6 4s 2
(iv)
1s 2 2s2 2p6 3s 2 3p 6 3d 7 4s 2
The elements with atomic numbers 35, 53 and 85 are all ________.
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(e)
(iii)
(i)
noble gases
(ii)
halogens
(iii)
heavy metals
(iv)
light metals
13. Electronic configurations of four elements A, B, C and D are given below :
(A)
1s 2 2s2 2p6
(B) 1s2 2s 2 2p 4
(C)
1s 2 2s2 2p6 3s 1
(D) 1s2 2s 2 2p 5
Which of the following is the correct order of increasing tendency to gain
electron :
(i)
A<C<B<D
(ii)
A<B<C<D
(iii)
D<B<C<A
(iv)
D<A<B<C
II. Multiple Choice Questions (Type-II)
In the following questions two or more options may be correct.
14. Which of the following elements can show covalency greater than 4?
Be
(ii)
P
(iii)
S
no
(i)
(iv)
B
15. Those elements impart colour to the flame on heating in it, the atoms of which
require low energy for the ionisation (i.e., absorb energy in the visible region
of spectrum). The elements of which of the following groups will impart colour
to the flame?
(i)
2
(ii)
13
Exemplar Problems, Chemistry
30
(iii)
1
(iv)
17
16. Which of the following sequences contain atomic numbers of only
representative elements?
(i)
3, 33, 53, 87
(ii)
2, 10, 22, 36
(iii)
7, 17, 25, 37, 48
(iv)
9, 35, 51, 88
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17. Which of the following elements will gain one electron more readily in
comparison to other elements of their group?
(i)
S (g)
(ii)
Na (g)
(iii)
O (g)
(iv)
Cl (g)
18. Which of the following statements are correct?
(i)
Helium has the highest first ionisation enthalpy in the periodic table.
(ii)
Chlorine has less negative electron gain enthalpy than fluorine.
(iii)
Mercury and bromine are liquids at room temperature.
(iv)
In any period, atomic radius of alkali metal is the highest.
19. Which of the following sets contain only isoelectronic ions?
(i)
Zn2+, Ca2+ , Ga3+ , Al3+
(ii)
K +, Ca2+, Sc3+ , Cl –
(iii)
P , S , Cl , K
(iv)
Ti 4+, Ar, Cr3+, V 5+
3–
2–
–
+
20. In which of the following options order of arrangement does not agree with
the variation of property indicated against it?
Al 3+ < Mg2+ < Na+ < F– (increasing ionic size)
(ii)
B < C < N < O (increasing first ionisation enthalpy)
(iii)
I < Br < Cl < F (increasing electron gain enthalpy)
(iv)
Li < Na < K < Rb (increasing metallic radius)
no
(i)
21. Which of the following have no unit?
(i)
Electronegativity
(ii)
Electron gain enthalpy
(iii)
Ionisation enthalpy
(iv)
Metallic character
31
Classification of Elements and Periodicity in Properties
22. Ionic radii vary in
(i)
inverse proportion to the effective nuclear charge.
(ii)
inverse proportion to the square of effective nuclear charge.
(iii)
direct proportion to the screening effect.
(iv)
direct proportion to the square of screening effect.
23. An element belongs to 3 rd period and group-13 of the periodic table. Which of
the following properties will be shown by the element?
(i)
Liquid, metallic
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(ii)
Good conductor of electricity
(iii)
Solid, metallic
(iv)
Solid, non metallic
III. Short Answer Type
24. Explain why the electron gain enthalpy of fluorine is less negative than that
of chlorine.
25. All transition elements are d-block elements, but all d-block elements are not
transition elements. Explain.
26. Identify the group and valency of the element having atomic number 119. Also
predict the outermost electronic configuration and write the general formula
of its oxide.
27. Ionisation enthalpies of elements of second period are given below :
Ionisation enthalpy/ k cal mol –1 :
520, 899, 801, 1086, 1402, 1314,
1681, 2080.
Match the correct enthalpy
with the elements and
complete the graph given in
Fig. 3.1. Also write symbols
of elements with their
atomic number.
28. Among the elements B, Al,
C and Si,
which element has
the highest first
ionisation enthalpy?
(ii)
which element has
the most metallic
character?
no
(i)
Justify your answer
in each case.
Exemplar Problems, Chemistry
32
Fig. 3.1
29. Write four characteristic properties of p-block elements.
30. Choose the correct order of atomic radii of fluorine and neon (in pm) out of
the options given below and justify your answer.
(i) 72, 160
(ii)
(iii)
160, 160
72, 72
(iv)
160, 72
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31. Illustrate by taking examples of transition elements and non-transition
elements that oxidation states of elements are largely based on electronic
configuration.
32. Nitrogen has positive electron gain enthalpy whereas oxygen has negative.
However, oxygen has lower ionisation enthalpy than nitrogen. Explain.
33. First member of each group of representative elements (i.e., s and p-block
elements) shows anomalous behaviour. Illustrate with two examples.
34. p-Block elements form acidic, basic and amphoteric oxides. Explain each
property by giving two examples and also write the reactions of these oxides
with water.
35. How would you explain the fact that first ionisation enthalpy of sodium is
lower than that of magnesium but its second ionisation enthalpy is higher
than that of magnesium?
36. What do you understand by exothermic reaction and endothermic reaction?
Give one example of each type.
37. Arrange the elements N, P,
O and S in the order of(i)
increasing first
ionisation enthalpy.
(ii)
increasing
non
metallic character.
no
Give reason for the
arrangement assigned.
38. Explain the deviation in
ionisation enthalpy of
some elements from the
general trend by using
Fig. 3.2.
Fig. 3.2
33
Classification of Elements and Periodicity in Properties
39. Explain the following:
(a) Electronegativity of elements increase on moving from left to right in the
periodic table.
(b) Ionisation enthalpy decrease in a group from top to bottom?
40. How does the metallic and non metallic character vary on moving from left to
right in a period?
41. The radius of Na+ cation is less than that of Na atom. Give reason.
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42. Among alkali metals which element do you expect to be least electronegative
and why?
IV. Matching Type
43. Match the correct atomic radius with the element.
Element
Atomic radius (pm)
Be
74
C
88
O
111
B
77
N
66
44. Match the correct ionisation enthalpies and electron gain enthalpies of the
following elements.
Elements
Δ H1
Δ H2
Δeg H
(i) Most reactive non metal
(ii) Most reactive metal
A.
B.
419
1681
3051
3374
– 48
– 328
(iii) Least reactive element
(iv) Metal forming binary halide
C.
D.
738
2372
1451
5251
– 40
+ 48
45. Electronic configuration of some elements is given in Column I and their
electron gain enthalpies are given in Column II. Match the electronic
configuration with electron gain enthalpy.
Column (II)
no
Column (I)
Electronic configuration
Electron gain enthalpy/kJ mol –1
(i) 1s2 2s 2 sp6
(A)
– 53
(ii) 1s2 2s 2 2p6 3s1
(B)
– 328
(iii) 1s2 2s 2 2p 5
(C)
– 141
(iv) 1s2 2s 2 2p 4
(D)
+ 48
Exemplar Problems, Chemistry
34
V. Assertion and Reason Type
In the following questions a statement of Assertion (A) followed by a statement
of reason (R) is given. Choose the correct option out of the choices given
below each question.
46. Assertion (A) : Generally, ionisation enthalpy increases from left to right in a
period.
When successive electrons are added to the orbitals in the
same principal quantum level, the shielding effect of inner
core of electrons does not increase very much to compensate
for the increased attraction of the electron to the nucleus.
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Reason (R) :
(i)
Assertion is correct statement and reason is wrong statement.
(ii)
Assertion and reason both are correct statements and reason is correct
explanation of assertion.
(iii)
Assertion and reason both are wrong statements.
(iv)
Assertion is wrong statement and reason is correct statement.
47. Assertion (A) : Boron has a smaller first ionisation enthalpy than beryllium.
Reason (R) :
The penetration of a 2s electron to the nucleus is more than
the 2p electron hence 2p electron is more shielded by the
inner core of electrons than the 2s electrons.
(i)
Assertion and reason both are correct statements but reason is not
correct explanation for assertion.
(ii)
Assertion is correct statement but reason is wrong statement.
(iii)
Assertion and reason both are correct statements and reason is correct
explanation for assertion.
(iv)
Assertion and reason both are wrong statements.
48. Assertion (A) : Electron gain enthalpy becomes less negative as we go down
a group.
Reason (R) :
Size of the atom increases on going down the group and the
added electron would be farther from the nucleus.
Assertion and reason both are correct statements but reason is not
correct explanation for assertion.
(ii)
Assertion and reason both are correct statements and reason is correct
explanation for assertion.
no
(i)
(iii)
Assertion and reason both are wrong statements.
(iv)
Assertion is wrong statement but reason is correct statement.
VI. Long Answer Type
49. Discuss the factors affecting electron gain enthalpy and the trend in its
variation in the periodic table.
35
Classification of Elements and Periodicity in Properties
50. Define ionisation enthalpy. Discuss the factors affecting ionisation enthalpy
of the elements and its trends in the periodic table.
51. Justify the given statement with suitable examples— “the Properties of the
elements are a periodic function of their atomic numbers”.
52. Write down the outermost electronic configuration of alkali metals. How will
you justify their placement in group 1 of the periodic table?
53. Write the drawbacks in Mendeleev’s periodic table that led to its modification.
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54. In what manner is the long form of periodic table better than Mendeleev’s
periodic table? Explain with examples.
no
55. Discuss and compare the trend in ionisation enthalpy of the elements of
group1 with those of group17 elements.
Exemplar Problems, Chemistry
36
ANSWERS
I. Multiple Choice Questions (Type-I)
1. (ii)
2. (iv)
3. (i)
4. (i)
5. (iii)
7. (iii)
8. (iii)
9. (iii)
10. (iv)
11. (iii)
12.(a) (iii), (b) (iii), (c) (iii), (d) (i), (e) (ii)
6. (iii)
13. (i)
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II. Multiple Choice Questions (Type-II)
14. (ii), (iii)
15. (i), (iii)
16. (i), (iv)
17. (i), (iv)
18. (i), (iii), (iv)
19. (ii), (iii)
20. (ii), (iii)
21. (i), (iv)
22. (i), (iii)
23. (i), (iii)
III. Short Answer Type
24.
The added electron in fluorine goes to second quantum level. Due to small
size of fluorine it experiences repulsion from other electrons much more
in comparison to that in chlorine because in chlorine, the electron is added
to 3rd quantum level in which larger space is available for movement.
26.
Group : 1, Valency : 1
Outermost electronic configuration = 8s1
Formula of Oxide = M2O
27.
Compare your plot with the plot given in the textbook.
28.
(i) Carbon
(ii) Aluminium
(i)
32.
The outermost electronic configuraton of nitrogen (2s 2 2p 1x 2p 1y 2p 1z) is very
stable because p-orbital is half filled. Addition of extra electron to any of
the 2p orbital requires energy.
no
30.
Oxygen has 4 electrons in 2p orbitals and acquires stable configuration
i.e., 2p 3 configuration after removing one electron.
35.
After removing 1 electron from the sodium atom the ion formed acquires
the configuration of inert gas, neon. The second electron is removed from
one of the 2p-orbitals which are completely filled i.e., have a total of 6
electrons and are closer to the nucleus.
37
Classification of Elements and Periodicity in Properties
37.
(i) S < P < N < O
(ii) P < S < N < O
39.
(a) Decrease in size of atom and increase in nuclear charge.
(b) Increase in atomic size.
Metallic character decreases and non metallic character increases in moving
from left to right in a period. It is due to increase in ionisation enthalpy
and electron gain enthalpy.
41.
Decrease of one shell.
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40.
42.
Electronegativity decreases in a group from top to bottom. Thus, caesium
is the least electronegative element.
IV. Matching Type
43.
Be = 111, O = 66, C = 77, B = 88, N = 74.
44.
Most reactive non metal = B, Most reactive metal = A, Least reactive
element = D, Metal forming binary halide = C
45.
(i) ⎯→ (D);
(ii) ⎯→ (A)
V. Assertion and Reason Type
(ii)
47.
(iii)
48.
(iv)
no
46.
Exemplar Problems, Chemistry
38
(iii) ⎯→ (B)
(iv) ⎯→ (C)
Unit
4
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CHEMIC
AL BONDING AND
CHEMICAL
AR SSTRUC
TRUC
TURE
MOLECUL
MOLECULAR
TRUCTURE
I. Multiple Choice Questions (Type-I)
1.
2.
(i)
[NF3 and BF3]
(ii)
[BF4 and NH4 ]
(iii)
[BCl3 and BrCl3]
(iv)
[NH 3 and NO3 ]
–
+
–
Polarity in a molecule and hence the dipole moment depends primarily on
electronegativity of the constituent atoms and shape of a molecule. Which of
the following has the highest dipole moment?
(i)
CO2
(ii)
HI
(iii)
H2O
(iv)
SO2
+
4.
–
+
The types of hybrid orbitals of nitrogen in NO2 , NO3 and NH4 respectively are
expected to be
(i)
sp, sp3 and sp2
(ii)
sp, sp2 and sp3
no
3.
Isostructural species are those which have the same shape and hybridisation.
Among the given species identify the isostructural pairs.
(iii)
sp2, sp and sp3
(iv)
sp2, sp3 and sp
Hydrogen bonds are formed in many compounds e.g., H2O, HF, NH3 . The
boiling point of such compounds depends to a large extent on the strength
of hydrogen bond and the number of hydrogen bonds. The correct decreasing
order of the boiling points of above compounds is :
(i)
HF > H2O > NH3
(ii)
H2O > HF > NH3
(iii)
NH3 > HF > H2O
(iv)
NH3 > H 2O > HF
5. In PO 43– ion the formal charge on the oxygen atom of P–O bond is
(i)
+1
(ii)
–1
(iii)
– 0.75
(iv)
+ 0.75
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6. In NO 3– ion, the number of bond pairs and lone pairs of electrons on nitrogen
atom are
(i)
2, 2
(ii)
3, 1
(iii)
1, 3
(iv)
4, 0
7. Which of the following species has tetrahedral geometry?
(i)
BH4–
(ii)
NH2–
(iii)
CO3
(iv)
H3O+
2–
8. Number of π bonds and σ bonds in the following structure is–
6, 19
(ii)
4, 20
(iii)
5, 19
(iv)
5, 20
no
(i)
9.
Which molecule/ion out of the following does not contain unpaired electrons?
+
(i)
N2
(ii)
O2
(iii)
O2
(iv)
B2
2–
Exemplar Problems, Chemistry
40
10. In which of the following molecule/ion all the bonds are not equal?
(i)
XeF4
(ii)
BF 4
(iii)
C2H4
(iv)
SiF4
–
11. In which of the following substances will hydrogen bond be strongest?
HCl
(ii)
H 2O
(iii)
HI
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(i)
(iv)
H2S
12. If the electronic configuration of an element is 1s 2 2s2 2p6 3s 2 3p 6 3d2 4s2, the
four electrons involved in chemical bond formation will be_____.
(i)
3p6
(ii)
3p6, 4s 2
(iii)
3p6, 3d2
(iv)
3d2, 4s2
13. Which of the following angle corresponds to sp2 hybridisation?
(i)
90°
(ii)
120°
(iii)
180°
(iv)
109°
The electronic configurations of three elements, A, B and C are given below.
Answer the questions 14 to 17 on the basis of these configurations.
A
1s 2
2s 2
2p6
B
1s 2
2s 2
2p6
3s 2
3p3
C
1s 2
2s 2
2p6
3s 2
3p5
14. Stable form of A may be represented by the formula :
A
(ii)
A2
(iii)
A3
(iv)
A4
no
(i)
15. Stable form of C may be represented by the formula :
(i)
C
(ii)
C2
41
Chemical Bonding and Molecular Structure
(iii)
C3
(iv)
C4
16. The molecular formula of the compound formed from B and C will be
(i)
BC
(ii)
B2C
(iii)
BC2
(iv)
BC3
17. The bond between B and C will be
Ionic
(ii)
Covalent
(iii)
Hydrogen
(iv)
Coordinate
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(i)
18. Which of the following order of energies of molecular orbitals of N2 is correct?
(i)
(π2py ) < (σ2pz) < (π*2px) ≈ (π*2py )
(ii)
(π2py ) > (σ2pz) > (π*2px) ≈ (π*2py )
(iii)
(π2py ) < (σ2pz) > (π*2px) ≈ (π*2py )
(iv)
(π2py ) > (σ2pz) < (π*2px) ≈ (π*2py )
19. Which of the following statement is not correct from the view point of molecular
orbital theory?
(i)
Be2 is not a stable molecule.
(ii)
He2 is not stable but He2 is expected to exist.
(iii)
Bond strength of N2 is maximum amongst the homonuclear diatomic
molecules belonging to the second period.
(iv)
The order of energies of molecular orbitals in N2 molecule is
+
σ2s < σ* 2s < σ2p z < (π2px = π2py ) < (π* 2px = π* 2py ) < σ *2p z
20. Which of the following options represents the correct bond order :
(i)
O2– > O2 > O+2
(ii)
O2 < O2 < O2
(iii)
O2– > O2 < O2+
(iv)
O2 < O2 > O2
–
+
no
–
+
21. The electronic configuration of the outer most shell of the most electronegative
element is
(i)
2s22p5
(ii)
3s23p5
(iii)
4s24p5
(iv)
5s25p5
Exemplar Problems, Chemistry
42
22. Amongst the following elements whose electronic configurations are given
below, the one having the highest ionisation enthalpy is
(i)
[Ne]3s 23p1
(ii)
[Ne]3s 23p3
(iii)
[Ne]3s 23p2
(iv)
[Ar]3d 104s 24p 3
II. Multiple Choice Questions (Type-II)
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In the following questions two or more options may be correct.
23. Which of the following have identical bond order?
–
(i)
CN
(ii)
NO+
(iii)
O –2
(iv)
O2
2–
24. Which of the following attain the linear structure:
(i)
BeCl 2
(ii)
NCO+
(iii)
NO2
(iv)
CS 2
25. CO is isoelectronic with
+
(i)
NO
(ii)
N2
(iii)
SnCl2
(iv)
NO2
–
26. Which of the following species have the same shape?
(i)
CO2
(ii)
CCl4
(iii)
O3
(iv)
NO2
no
–
27. Which of the following statements are correct about CO32– ?
(i)
The hybridisation of central atom is sp3.
(ii)
Its resonance structure has one C–O single bond and two C=O double
bonds.
(iii)
The average formal charge on each oxygen atom is 0.67 units.
(iv)
All C–O bond lengths are equal.
43
Chemical Bonding and Molecular Structure
28. Dimagnetic species are those which contain no unpaired electrons. Which
among the following are dimagnetic?
(i)
N2
(ii)
N22–
(iii)
O2
(iv)
O22–
29. Species having same bond order are :
N2
(ii)
N2–
(iii)
F2
(iv)
O2–
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(i)
+
30. Which of the following statements are not correct?
(i)
NaCl being an ionic compound is a good conductor of electricity in the
solid state.
(ii)
In canonical structures there is a difference in the arrangement of atoms.
(iii)
Hybrid orbitals form stronger bonds than pure orbitals.
(iv)
VSEPR Theory can explain the square planar geometry of XeF4.
III. Short Answer Type
31. Explain the non linear shape of H2S and non planar shape of PCl3 using valence
shell electron pair repulsion theory.
32. Using molecular orbital theory, compare the bond energy and magnetic
character of O +2 and O–2 species.
33. Explain the shape of BrF 5.
no
34. Structures of molecules of two compounds are given below :
Exemplar Problems, Chemistry
44
(a) Which of the two compounds will have intermolecular hydrogen bonding
and which compound is expected to show intramolecular hydrogen
bonding.
(b) The melting point of a compound depends on, among other things, the
extent of hydrogen bonding. On this basis explain which of the above
two compounds will show higher melting point.
(c) Solubility of compounds in water depends on power to form hydrogen
bonds with water. Which of the above compounds will form hydrogen
bond with water easily and be more soluble in it.
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35. Why does type of overlap given in the following figure not result in bond
formation?
36. Explain why PCl5 is trigonal bipyramidal whereas IF5 is square pyramidal.
37. In both water and dimethyl ether ( CH3 — Ο — CH3 ), oxygen atom is central
atom, and has the same hybridisation, yet they have different bond angles.
Which one has greater bond angle? Give reason.
38. Write Lewis structure of the following compounds and show formal charge
on each atom.
HNO3, NO2, H2SO4
39. The energy of σ2pz molecular orbital is greater than π2px and π2py molecular
orbitals in nitrogen molecule. Write the complete sequence of energy levels in
the increasing order of energy in the molecule. Compare the relative stability
and the magnetic behaviour of the following species :
+
–
2+
N2, N2 , N2 , N2
40. What is the effect of the following processes on the bond order in N2 and O2?
N2 → N2 + e–
no
(i)
+
O2 → O2 + e–
+
(ii)
41. Give reasons for the following :
(i)
Covalent bonds are directional bonds while ionic bonds are nondirectional.
(ii)
Water molecule has bent structure whereas carbon dioxide molecule is
linear.
(iii)
Ethyne molecule is linear.
45
Chemical Bonding and Molecular Structure
42. What is an ionic bond? With two suitable examples explain the difference
between an ionic and a covalent bond?
43. Arrange the following bonds in order of increasing ionic character giving
reason.
N—H, F—H, C—H and O—H
2–
44. Explain why CO3 ion cannot be represented by a single Lewis structure. How
can it be best represented?
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45. Predict the hybridisation of each carbon in the molecule of organic compound
given below. Also indicate the total number of sigma and pi bonds in this
molecule.
46. Group the following as linear and non-linear molecules :
H 2O, HOCl, BeCl2, Cl2O
47. Elements X, Y and Z have 4, 5 and 7 valence electrons respectively. (i) Write
the molecular formula of the compounds formed by these elements individually
with hydrogen. (ii) Which of these compounds will have the highest dipole
moment?
48. Draw the resonating structure of
(i) Ozone molecule
(ii) Nitrate ion
49. Predict the shapes of the following molecules on the basis of hybridisation.
BCl3, CH4, CO2, NH3
2–
50. All the C—O bonds in carbonate ion (CO3 ) are equal in length. Explain.
51. What is meant by the term average bond enthalpy? Why is there difference in
bond enthalpy of O—H bond in ethanol (C 2H 5OH) and water?
IV. Matching Type
no
52. Match the species in Column I with the type of hybrid orbitals in Column II.
Column I
Column II
(i)
SF4
(a) sp3d2
(ii)
IF5
(b) d2sp3
+
2
+
4
(iii)
NO
(c) sp3d
(iv)
NH
(d) sp3
(e) sp
Exemplar Problems, Chemistry
46
53. Match the species in Column I with the geometry/shape in Column II.
Column I
Column II
+
(i)
H3O
(a) Linear
(ii)
HC ≡ CH
(b) Angular
–
2
+
4
(iii)
ClO
(c) Tetrahedral
(iv)
NH
(d) Trigonal bipyramidal
(e) Pyramidal
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54. Match the species in Column I with the bond order in Column II.
Column I
Column II
(i)
NO
(a) 1.5
(ii)
CO
(b) 2.0
(iii)
–
2
O
(c) 2.5
(iv)
O2
(d) 3.0
55. Match the items given in Column I with examples given in Column II.
Column I
Column II
(i)
Hydrogen bond
(a) C
(ii)
Resonance
(b) LiF
(iii)
Ionic solid
(c) H2
(iv)
Covalent solid
(d) HF
(e) O3
56. Match the shape of molecules in Column I with the type of hybridisation in
Column II.
Column I
Column II
(i)
Tetrahedral
(a) sp2
(ii)
Trigonal
(b) sp
(iii)
Linear
(c) sp3
no
V. Assertion and Reason Type
In the following questions a statement of Assertion (A) followed by a statement of
Reason (R) is given. Choose the correct option out of the choices given below each
question.
57. Assertion (A) : Sodium chloride formed by the action of chlorine gas on
sodium metal is a stable compound.
Reason (R) :
This is because sodium and chloride ions acquire octet in
sodium chloride formation.
47
Chemical Bonding and Molecular Structure
(i)
A and R both are correct, and R is the correct explanation of A.
(ii)
A and R both are correct, but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
A and R both are false.
58. Assertion (A) : Though the central atom of both NH3 and H2O molecules are
sp3 hybridised, yet H–N–H bond angle is greater than that of
H–O–H.
Reason (R) :
This is because nitrogen atom has one lone pair and oxygen
atom has two lone pairs.
A and R both are correct, and R is the correct explanation of A.
(ii)
A and R both are correct, but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
A and R both are false.
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(i)
59. Assertion (A): Among the two O–H bonds in H2O molecule, the energy
required to break the first O–H bond and the other O–H bond
is the same.
Reason (R) :
This is because the electronic environment around oxygen is
the same even after breakage of one O–H bond.
(i)
A and R both are correct, and R is correct explanation of A.
(ii)
A and R both are correct, but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
A and R both are false.
VI. Long Answer Type
60.
(i) Discuss the significance/ applications of dipole moment.
(ii) Represent diagrammatically the bond moments and the resultant dipole
moment in CO 2 , NF3 and CHCl3.
61. Use the molecular orbital energy level diagram to show that N2 would be
expected to have a triple bond, F2, a single bond and Ne2, no bond.
no
62. Briefly describe the valence bond theory of covalent bond formation by taking
an example of hydrogen. How can you interpret energy changes taking place
in the formation of dihydrogen?
63. Describe hybridisation in the case of PCl5 and SF6. The axial bonds are longer
as compared to equatorial bonds in PCl5 whereas in SF6 both axial bonds and
equatorial bonds have the same bond length. Explain.
64.
(i) Discuss the concept of hybridisation. What are its different types in a
carbon atom.
Exemplar Problems, Chemistry
48
(ii) What is the type of hybridisation of carbon atoms marked with star.
(a)
(b)
(c)
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(d)
(e)
Comprehension given below is followed by some multiple choice questions.
Each question has one correct option. Choose the correct option.
Molecular orbitals are formed by the overlap of atomic orbitals. Two atomic orbitals
combine to form two molecular orbitals called bonding molecular orbital (BMO)
and anti bonding molecular orbital (ABMO). Energy of anti bonding orbital is raised
above the parent atomic orbitals that have combined and the energy of the bonding
orbital is lowered than the parent atomic orbitals. Energies of various molecular
orbitals for elements hydrogen to nitrogen increase in the order :
σ1s < σ * 1s < σ 2s < σ * 2s < ( π 2 p x ≈ π 2 py ) < σ 2 pz < ( π * 2 px ≈ π * 2 py ) < σ * 2 p z and
for oxygen and fluorine order of energy of molecular orbitals is given below :
σ1s < σ * 1s < σ 2s < σ * 2s < σ 2 pz < ( π2 px π2 py ) < ( π * 2 px π * 2 py ) < σ * 2 p z
Different atomic orbitals of one atom combine with those atomic orbitals of the
second atom which have comparable energies and proper orientation. Further, if
the overlapping is head on, the molecular orbital is called ‘Sigma’, (σ) and if the
overlap is lateral, the molecular orbital is called ‘pi’, (π). The molecular orbitals
are filled with electrons according to the same rules as followed for filling of atomic
orbitals. However, the order for filling is not the same for all molecules or their
ions. Bond order is one of the most important parameters to compare the strength
of bonds.
65. Which of the following statements is correct?
In the formation of dioxygen from oxygen atoms 10 molecular orbitals
will be formed.
no
(i)
(ii)
All the molecular orbitals in the dioxygen will be completely filled.
(iii)
Total number of bonding molecular orbitals will not be same as total
number of anti bonding orbitals in dioxygen.
(iv)
Number of filled bonding orbitals will be same as number of filled anti
bonding orbitals.
49
Chemical Bonding and Molecular Structure
66. Which of the following molecular orbitals has maximum number of nodal
planes?
(i)
σ*1s
(ii)
σ*2p z
(iii)
π2px
(iv)
π*2py
67. Which of the following pair is expected to have the same bond order?
(i)
O2 , N2
(ii)
O2+ , N2–
+
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–
(iii)
O2 , N2
(iv)
O2–, N 2–
68. In which of the following molecules, σ2pz molecular orbital is filled after π2px
and π2py molecular orbitals?
O2
(ii)
Ne2
(iii)
N2
(iv)
F2
no
(i)
Exemplar Problems, Chemistry
50
ANSWERS
I. Multiple Choice Questions (Type-I)
1. (ii)
2. (iii)
3. (ii)
4. (ii)
5. (ii)
6. (iv)
7. (i)
8. (iii)
9. (iii)
10. (iii)
11. (ii)
12. (iv)
13. (ii)
14. (i)
15. (ii)
16. (iv)
17. (ii)
18. (i)
19. (iv)
20. (ii)
21. (i)
22. (ii)
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II. Multiple Choice Questions (Type-II)
23. (i), (ii)
24. (i), (iv)
25. (i), (ii)
26. (iii), (iv)
27. (iii), (iv)
28. (i), (iv)
29. (iii), (iv)
30. (i), (ii)
III. Short Answer Type
32.
(i)
According to molecular orbital theory electronic configurations of
+
–
O2 and O 2 species are as follows :
O2 : (σ1s) (σ* 1s ) (σ2s) (σ* 2s ) (σ2p z) (π2p2x , π2p 2y) (π* 2px1 )
+
2
2
2
2
2
O2– : (σ1s)2 (σ* 1s2 ) (σ2s)2 (σ* 2s2 ) (σ2pz) 2 (π2p2x , π2p2y ) (π* 2px2 , π*2py1)
Bond order of O+2 =
10 − 5
5
=
= 2.5
2
2
10 − 7 3
= = 1.5
2
2
Higher bond order of O2+ shows that it is more stable than O2– . Both the
species have unpaired electrons. So both are paramagnetic in nature.
–
Bond order of O2 =
(a)
Compound (I) will form intramolecular hydrogen bond because
NO 2 and OH group are close together in comparison to that in
compound (II).
no
34.
51
Chemical Bonding and Molecular Structure
Compound (II) will have higher melting point because it forms
intermolecular hydrogen bonds. Thus, more and more molecules
are joined together through hydrogen bond formation.
(c)
Due to intramolecular hydrogen bonding compound (I) will not be
able to form hydrogen bonds with water thus will be less soluble in
it while compound (II) can form hydrogen bond with water more
easily and will be soluble in water.
[Hint : Dimethyl ether will have larger bond angle. There will be more
repulsion between bond pairs of CH3 groups attached in ether than
between bond pairs of hydrogen atoms attached to oxygen in water. The
carbon of CH3 in ether is attached to three hydrogen atoms through σ
bonds and electron pairs of these bonds add to the electronic charge density
on carbon atom. Hence, repulsion between two —CH3 groups will be more
than that between two hydrogen atoms.]
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37.
(b)
IV. Matching Type
52.
(i) → (c)
(ii) → (a)
(iii) → (e)
(iv) → (d)
53.
(i) → (e)
(ii) → (a)
(iii) → (b)
(iv) → (c)
54.
(i) → (c)
(ii) → (d)
(iii) → (a)
(iv) → (b)
55.
(i) → (d)
(ii) → (e)
(iii) → (b)
(iv) → (a)
56.
(i) → (c)
(ii) → (a)
(iii) → (b)
V. Assertion and Reason Type
58. (i)
59. (iv)
65. (i)
66. (ii)
67. (ii)
no
57. (i)
Exemplar Problems, Chemistry
52
68. (iii)
Unit
5
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STATE
S OF MA
TTER
TES
MAT
I. Multiple Choice Questions (Type-I)
1.
2.
A person living in Shimla observed that cooking food without using pressure
cooker takes more time. The reason for this observation is that at high altitude:
(i)
(ii)
pressure increases
temperature decreases
(iii)
(iv)
pressure decreases
temperature increases
Which of the following property of water can be used to explain the spherical
shape of rain droplets?
(i)
(ii)
(iii)
surface tension
critical phenomena
(iv)
pressure
A plot of volume (V ) versus
temperature (T ) for a gas at
constant pressure is a
straight line passing
through the origin. The
plots at different values of
pressure are shown in
Fig. 5.1. Which of the
following order of pressure
is correct for this gas?
no
3.
viscosity
(i)
p 1 > p2 > p3 > p4
(ii)
p 1 = p2 = p3 = p4
(iii)
p 1 < p2 < p3 < p4
(iv)
p 1 < p2 = p3 < p4
Fig. 5.1
4.
(i)
charge of interacting particles
(ii)
mass of interacting particles
(iii)
polarisability of interacting particles
(iv)
strength of permanent dipoles in the particles.
Dipole-dipole forces act between the molecules possessing permanent dipole.
Ends of dipoles possess ‘partial charges’. The partial charge is
(i)
more than unit electronic charge
(ii)
equal to unit electronic charge
(iii)
less than unit electronic charge
(iv)
double the unit electronic charge
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5.
The interaction energy of London force is inversely proportional to sixth power
of the distance between two interacting particles but their magnitude depends
upon
6.
7.
8.
The pressure of a 1:4 mixture of dihydrogen and dioxygen enclosed in a vessel
is one atmosphere. What would be the partial pressure of dioxygen?
(i)
0.8×105 atm
(ii)
0.008 Nm–2
(iii)
8×10 Nm
(iv)
0.25 atm
4
–2
As the temperature increases, average kinetic energy of molecules increases.
What would be the effect of increase of temperature on pressure provided the
volume is constant?
(i)
increases
(ii)
decreases
(iii)
remains same
(iv)
becomes half
Gases possess characteristic critical temperature which depends upon the
magnitude of intermolecular forces between the particles. Following are the
critical temperatures of some gases.
Gases
H2
He
O2
N2
33.2
5.3
154.3
126
Critical temperature
no
in Kelvin
From the above data what would be the order of liquefaction of these gases?
Start writing the order from the gas liquefying first
(i)
H2, He, O2, N 2
(ii)
He, O2, H2, N2
(iii)
N2, O2, He, H2
(iv)
O2, N2, H2, He
Exemplar Problems, Chemistry
54
9. What is SI unit of viscosity coefficient (η)?
(i)
Pascal
(ii)
Nsm–2
(iii)
km –2 s
(iv)
N m–2
10. Atmospheric pressures recorded in different cities are as follows:
Shimla
Bangalore
Delhi
Mumbai
p in N/m2
1.01×105
1.2×105
1.02×105
1.21×105
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Cities
Consider the above data and mark the place at which liquid will boil first.
(i)
Shimla
(ii)
Bangalore
(iii)
Delhi
(iv)
Mumbai
11. Which curve in Fig. 5.2
represents the curve of ideal
gas?
(i) B only
(ii)
C and D only
(iii)
E and F only
(iv)
A and B only
12. Increase in kinetic energy can
overcome intermolecular
forces of attraction. How will
the viscosity of liquid be
affected by the increase in
temperature?
Increase
(ii)
No effect
(iii)
Decrease
(iv)
No regular pattern will be followed
Fig. 5.2
no
(i)
13. How does the surface tension of a liquid vary with increase in temperature?
(i)
Remains same
(ii)
Decreases
(iii)
Increases
(iv)
No regular pattern is followed
55
States of Matter
II. Multiple Choice Questions (Type-II)
In the following questions two or more options may be correct.
14. With regard to the gaseous state of matter which of the following statements
are correct?
Complete order of molecules
(ii)
Complete disorder of molecules
(iii)
Random motion of molecules
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(i)
(iv)
Fixed position of molecules
15. Which of the following figures does not represent 1 mole of dioxygen gas at
STP?
(i)
16 grams of gas
(ii)
22.7 litres of gas
(iii)
6.022 × 10 dioxygen molecules
(iv)
11.2 litres of gas
23
16. Under which of the following two conditions applied together, a gas deviates
most from the ideal behaviour?
(i)
Low pressure
(ii)
High pressure
(iii)
Low temperature
(iv)
High temperature
17. Which of the following changes decrease the vapour pressure of water kept in
a sealed vessel?
Decreasing the quantity of water
(ii)
Adding salt to water
(iii)
Decreasing the volume of the vessel to one-half
(iv)
Decreasing the temperature of water
no
(i)
III. Short Answer Type
18. If 1 gram of each of the following gases are taken at STP, which of the gases
will occupy (a) greatest volume and (b) smallest volume?
CO,
H 2O,
CH4,
Exemplar Problems, Chemistry
56
NO
19. Physical properties of ice, water and steam are very different. What is the
chemical composition of water in all the three states.
20. The behaviour of matter in different states is governed by various physical
laws. According to you what are the factors that determine the state of matter?
Use the information and data given below to answer the questions (a) to (c):
•
Stronger intermolecular forces result in higher boiling point.
•
Strength of London forces increases with the number of electrons in the
molecule.
•
Boiling point of HF, HCl, HBr and HI are 293 K, 189 K, 206 K and
238 K respectively.
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21.
(a) Which type of intermolecular forces are present in the molecules
HF, HCl, HBr and HI?
(b) Looking at the trend of boiling points of HCl, HBr and HI, explain
out of dipole-dipole interaction and London interaction, which one
is predominant here.
(c)
Why is boiling point of hydrogen fluoride highest while that of
hydrogen chloride lowest?
22. What will be the molar volume of nitrogen and argon at 273.15K and 1 atm?
23. A gas that follows Boyle’s law, Charle’s law and Avogadro’s law is called an
ideal gas. Under what conditions a real gas would behave ideally?
24. Two different gases ‘A’ and ‘B’ are filled in separate containers of equal capacity
under the same conditions of temperature and pressure. On increasing the
pressure slightly the gas ‘A’ liquefies but gas B does not liquify even on applying
high pressure until it is cooled. Explain this phenomenon.
25. Value of universal gas constant (R) is same for all gases. What is its physical
significance?
26. One of the assumptions of kinetic theory of gases states that “there is no force
of attraction between the molecules of a gas.” How far is this statement correct?
Is it possible to liquefy an ideal gas? Explain.
no
27. The magnitude of surface tension of liquid depends on the attractive forces
between the molecules. Arrange the following in increasing order of surface
tension :
water, alcohol (C2H5OH) and hexane [CH3(CH2)4CH3)].
28. Pressure exerted by saturated water vapour is called aqueous tension. What
correction term will you apply to the total pressure to obtain pressure of
dry gas?
29. Name the energy which arises due to motion of atoms or molecules in a body.
How is this energy affected when the temperature is increased?
57
States of Matter
30. Name two intermolecular forces that exist between HF molecules in liquid
state.
31. One of the assumptions of kinetic theory of gases is that there is no force of
attraction between the molecules of a gas.
State and explain the evidence that shows that the assumption is not applicable
for real gases.
32. Compressibility factor, Z, of a gas is given as Z =
What is the value of Z for an ideal gas?
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(i)
pV
nRT
(ii)
For real gas what will be the effect on value of Z above Boyle’s temperature?
33. The critical temperature (Tc) and critical pressure ( pc ) of CO2 are 30.98°C and
73 atm respectively. Can CO2 ( g) be liquefied at 32°C and 80 atm pressure?
34. For real gases the relation between p, V and T is given by van der Waals
equation:
2
⎛
an ⎞
⎜⎝ p + V 2 ⎟⎠ (V -n b) = n RT
where ‘a’ and ‘b’ are van der Waals constants, ‘nb’ is approximately equal to
the total volume of the molecules of a gas.
‘a’ is the measure of magnitude of intermolecular attraction.
(i)
Arrange the following gases in the increasing order of ‘b’. Give reason.
O2, CO2, H2, He
(ii)
Arrange the following gases in the decreasing order of magnitude of ‘a’.
Give reason.
CH4, O2, H2
35. The relation between pressure exerted by an ideal gas (p ideal) and observed
pressure (preal) is given by the equation
an
V
2
2
no
p ideal
= p re al +
If pressure is taken in Nm –2, number of moles in mol and volume in m3,
Calculate the unit of ‘a’.
What will be the unit of ‘a’ when pressure is in atmosphere and volume in
dm3?
36. Name two phenomena that can be explained on the basis of surface tension.
Exemplar Problems, Chemistry
58
37. Viscosity of a liquid arises due to strong intermolecular forces existing between
the molecules. Stronger the intermolecular forces, greater is the viscosity.
Name the intermolecular forces existing in the following liquids and arrange
them in the increasing order of their viscosities. Also give reason for the
assigned order in one line.
Water, hexane (CH3CH2CH2CH2CH2CH3), glycerine (CH2OH CH(OH) CH2OH)
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38. Explain the effect of increasing the temperature of a liquid, on intermolecular
forces operating between its particles, what will happen to the viscosity of a
liquid if its temperature is increased?
39. The variation of pressure with
volume of the gas at different
temperatures
can
be
graphically represented as
shown in Fig. 5.3.
On the basis of this graph
answer the following questions.
How will the volume of a
gas change if its pressure
is increased at constant
temperature?
(ii)
At a constant pressure,
how will the volume of a
gas change if the
temperature is increased
from 200K to 400K?
Fig. 5.3
Pressure versus volume graph
for a real gas and an ideal gas
are shown in Fig. 5.4. Answer
the following questions on the
basis of this graph.
(i)
Interpret the behaviour
of real gas with respect to
ideal gas at low pressure.
(ii)
Interpret the behaviour
of real gas with respect
to ideal gas at high
pressure.
(iii)
Mark the pressure and
volume by drawing a
line at the point where
real gas behaves as an
ideal gas.
no
40.
(i)
Fig. 5.4
59
States of Matter
IV. Matching Type
41. Match the graphs between the following variables with their names :
Graphs
Names
(i)
Pressure vs temperature
graph at constant molar volume.
(a)
Isotherms
(ii)
Pressure vs volume graph
at constant temperature.
(b)
Constant temperature curve
Volume vs temperature graph
at constant pressure.
(c)
Isochores
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(iii)
(d) Isobars
42. Match the following gas laws with the equation representing them.
(i) Boyle’s law
(a) V ∝ n at constant T and p
(ii) Charle’s law
(b) p Total = p1 + p2 + p3+...... at constant T, V
(iii) Dalton’s law
(c)
(iv) Avogadro law
(d) V ∝ T at constant n and p
(e)
pV
= Constant
T
p∝
1
at constant n and T
V
43. Match the following graphs of ideal gas with their co-ordinates :
Graphical representation
x and y co-ordinates
(a)
pV vs. V
(ii)
(b)
p vs. V
(c)
p vs.
no
(i)
(iii)
Exemplar Problems, Chemistry
60
1
V
V. Assertion and Reason Type
In the following questions a statement of Assertion (A) followed by a statement
of Reason (R) is given. Choose the correct option out of the choices given
below each question.
44. Assertion (A): Three states of matter are the result of balance between
intermolecular forces and thermal energy of the molecules.
Reason (R):
Both A and R are true and R is the correct explanation of A.
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(i)
Intermolecular forces tend to keep the molecules together but
thermal energy of molecules tends to keep them apart.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
A is false but R is true.
45. Assertion (A): At constant temperature, pV vs V plot for real gases is not a
straight line.
Reason (R) :
At high pressure all gases have Z > 1 but at intermediate
pressure most gases have Z < 1.
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
A is false but R is true.
46. Assertion (A): The temperature at which vapour pressure of a liquid is equal
to the external pressure is called boiling temperature.
Reason (R) :
At high altitude atmospheric pressure is high.
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
A is false but R is true.
47. Assertion (A): Gases do not liquefy above their critical temperature, even
on applying high pressure.
no
Reason (R) :
Above critical temperature, the molecular speed is high and
intermolecular attractions cannot hold the molecules together
because they escape because of high speed.
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
A is false but R is true.
48. Assertion (A): At critical temperature liquid passes into gaseous state
imperceptibly and continuously.
61
States of Matter
Reason (R) :
The density of liquid and gaseous phase is equal to critical
temperature.
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
A is false but R is true.
49. Assertion (A): Liquids tend to have maximum number of molecules at their
surface.
Small liquid drops have spherical shape.
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Reason (R) :
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
A is false but R is true.
VI. Long Answer Type
50. Isotherms of carbon dioxide
at various temperatures are
represented in Fig. 5.5.
Answer the following questions
based on this figure.
In which state will CO2
exist between the points
a and b at temperature
T 1?
(ii)
At what point will CO2
start liquefying when
temperature is T1?
(iii)
At what point will CO2 be
completely liquefied
when temperature is T 2.
(iv)
Will condensation take
place
when
the
temperature is T 3.
no
(i)
(v)
What portion of the
isotherm at T1 represent
liquid and gaseous CO 2
at equilibrium?
Fig. 5.5
51. The variation of vapour pressure of different liquids with temperature is shown
in Fig. 5.6.
(i)
Calculate graphically boiling points of liquids A and B.
Exemplar Problems, Chemistry
62
If we take liquid C in a closed vessel and heat it continuously. At what
temperature will it boil?
(iii)
At high altitude, atmospheric pressure is low (say 60 mm Hg). At what
temperature liquid D boils?
(iv)
Pressure cooker is used for cooking food at hill station. Explain in terms
of vapour pressure why is it so?
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(ii)
no
Fig. 5.6
52. Why does the boundary between liquid phase and gaseous phase disappear
on heating a liquid upto critical temperature in a closed vessel? In this situation
what will be the state of the substance?
53. Why does sharp glass edge become smooth on heating it upto its melting
point in a flame? Explain which property of liquids is responsible for this
phenomenon.
63
States of Matter
54. Explain the term ‘laminar flow’. Is the velocity of molecules same in all the
layers in laminar flow? Explain your answer.
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55. Isotherms of carbon dioxide gas are shown in Fig. 5.7. Mark a path for
changing gas into liquid such that only one phase (i.e., either a gas or a liquid)
exists at any time during the change. Explain how the temperature, volume
and pressure should be changed to carry out the change.
no
Fig. 5.7
Exemplar Problems, Chemistry
64
ANSWERS
I. Multiple Choice Questions (Type-I)
1. (iii)
2. (ii)
3. (iii)
4. (iii)
5. (iii)
6. (iii)
7. (i)
8. (iv)
9. (ii)
10. (i)
11. (i)
12. (iii)
13. (ii)
II. Multiple Choice Questions (Type-II)
15. (i), (iv)
16. (ii), (iii)
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14. (ii), (iii)
17. (ii), (iv)
III. Short Answer Type
18.
a. CH4
b. NO
19.
Remains the same i.e., H2O.
20.
Pressure, temperature, mass and volume
21.
(a)
In HCl, HBr and HI, dipole-dipole and London forces because
molecules possess permanent dipole. In HF dipole-dipole, London
forces and hydrogen bonding.
(b)
Electronegativity of chlorine, bromine and iodine decreases in the
order :
Cl > Br > I
Therefore, dipole moment should decrease from HCl to HI. Thus,
dipole-dipole interaction should decrease from HCl to HI. But boiling
point increases on moving from HCl to HI. This means that London
forces are predominant. This is so because London forces increase
as the number of electrons in a molecule increases and in this case
number of electrons is increasing from HCl towards HI.
(c)
Hydrogen fluoride has highest dipole moment due to highest
electronegativity of fluorine and hydrogen bonding is also present in
it. Therefore, HF has highest boiling point.
22.4 litre
23.
Low pressure and high temperature
24.
Gas ‘A’ is at or below its critical temperature and gas ‘B’ is at a temperature
higher than critical temperature.
25.
Unit of R depends upon those units in which p, V and T are measured,
no
22.
pV
. If pressure is measured in Pascal, per mole volume is measured
nT
in m3 and temperature is measured in Kelven then. Units of ‘R’ are
–1
–1
–1
–1
Pam3K mol or J mol K . Jule is the unit of work done so ‘R’ is work
done per mole per kelvin.
R=
65
States of Matter
26.
In the absence of intermolecular forces of attraction, it will not be possible
to liquefy ideal gas.
27.
hexane < alcohol < water
28.
PDry gas = PTotal – aqueous tension
29.
Thermal energy. It is a measure of average kinetic energy of particles. It
increases with increase in temperature.
30.
(i)
Dipole - dipole interaction
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(ii) Hydrogen - bonding
31.
Real gases can be liquefied on cooling and compressing proving that forces
of attraction exist between the molecules.
32.
(i)
Z = 1 for ideal gas
(ii)
For a real gas Z > 1 above Boyle’s temperature.
33.
CO2 cannot be liquefied at 32°C by applying a pressure of 80 atm. This is
because the temperature is greater than critical temperature of CO2.
34.
(i)
H 2 < He < O2 < CO2 because size increases in the same order.
(ii)
CH 4 > O2 > H 2 intermolecular attractions are the highest in CH4 and
lowest in H 2 because intermolecular forces increase with number of
electrons in a molecule.
35.
an
pideal = p re al +
2
2
V
We write the known units in the above equation.
2
–2
Nm = Nm
–2
+
a . mol
3 2
(m )
If two values with same units are added then the units of result are same
as added units.
2
Nm
no
∴
-2
=
a .mol
m
6
–2
a =
Nm .m
6
2
mol
a = Nm4 mol–2
Similarly, when p is in atm and volume in dm3
3 2
a =
atm(dm )
2
mol
Exemplar Problems, Chemistry
= atm dm6 mol–2
66
36.
37.
(i)
Rise or fall of the liquid in a capillary - capillary action.
(ii)
Spherical shape of small liquid drops.
In water and glycerine – Hydrogen bonding. Hexane – Dispersion forces/
London forces. The order of viscosities of these liquids is hexane < water
< glycerine.
Hexane has weakest intermolecular forces and glycerine the strongest.
(three OH groups). Therefore, hexane has minimum viscosity and glycerine
has maximum viscosity.
The viscosity of a liquid decreases with the increase in temperature since
the kinetic energy of the molecules can overcome intermolecular forces.
So the liquid can flow more easily.
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38.
39.
(1)
The volume of a gas will decrease if the pressure on the gas is increased
keeping the temperature constant.
(2)
On increasing temperature, the volume of a gas will increase if the
pressure is kept constant.
IV. Matching Type
41.
(i) → (c)
(ii) → (a)
(iii) → (d)
42.
(i) → (e)
(ii) → (d)
(iii) → (b)
43.
(i) → (b)
(ii) → (c)
(iii) → (a)
(iv)→ (a)
V. Assertion and Reason Type
44. (i)
45. (ii)
46. (iii)
47. (i)
48. (i)
49. (iv)
VI. Long Answer Type
50.
(i)
(iii)
(ii)
at point b
at point g
(iv)
No, since T 3 > Tc
(v)
between b and c.
(i)
Boiling point of A = approximately 315 K, B = approximately 345 K
(ii)
Will not boil
(iii)
approximately 313 K
(iv)
A liquid boils when vapour pressure becomes equal to the
atmospheric pressure. Water boils at low temperature on hills
because atmospheric pressure is low. Therefore even at low
temperature vapour pressure becomes equal to atmospheric
pressure.
no
51.
gaseous state
67
States of Matter
Unit
6
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THERMODYNAMICS
I. Multiple Choice Questions (Type-I)
1.
2.
(i)
energy changes involved in a chemical reaction.
(ii)
the extent to which a chemical reaction proceeds.
(iii)
the rate at which a reaction proceeds.
(iv)
the feasibility of a chemical reaction.
Which of the following statements is correct?
(i)
The presence of reacting species in a covered beaker is an example of
open system.
(ii)
There is an exchange of energy as well as matter between the system
and the surroundings in a closed system.
(iii)
The presence of reactants in a closed vessel made up of copper is an
example of a closed system.
(iv)
The presence of reactants in a thermos flask or any other closed insulated
vessel is an example of a closed system.
The state of a gas can be described by quoting the relationship between___.
(i)
pressure, volume, temperature
(ii)
temperature, amount, pressure
no
3.
Thermodynamics is not concerned about______.
4.
(iii)
amount, volume, temperature
(iv)
pressure, volume, temperature, amount
The volume of gas is reduced to half from its original volume. The specific
heat will be ______.
(i)
reduce to half
(ii)
be doubled
6.
7.
8.
remain constant
(iv)
increase four times
During complete combustion of one mole of butane, 2658 kJ of heat is released.
The thermochemical reaction for above change is
(i)
2C 4H 10(g) + 13O2(g) ⎯→ 8CO2(g) + 10H2O(l ) ΔcH = –2658.0 kJ mol
(ii)
C4H10(g) +
13
O (g) ⎯→ 4CO2 (g) + 5H2O (g) Δ cH = –1329.0 kJ mol–1
2 2
(iii)
C4H10(g) +
13
–1
O (g) ⎯→ 4CO2 (g) + 5H2O (l ) Δ cH = –2658.0 kJ mol
2 2
(iv)
C4H10 (g) +
13
O (g) ⎯→ 4CO2 (g) + 5H2O (l ) Δ cH = +2658.0 kJ mol–1
2 2
–1
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5.
(iii)
V
Δf U of formation of CH4 (g) at certain temperature is –393 kJ mol–1. The
value of Δ f H V is
(i)
zero
(ii)
< Δf U V
(iii)
> Δf U V
(iv)
equal to Δf U
V
In an adiabatic process, no transfer of heat takes place between system and
surroundings. Choose the correct option for free expansion of an ideal gas
under adiabatic condition from the following.
(i)
q = 0, ΔT ≠ 0, w = 0
(ii)
q ≠ 0, ΔT = 0, w = 0
(iii)
q = 0, ΔT = 0, w = 0
(iv)
q = 0, ΔT < 0, w ≠ 0
The pressure-volume work for an ideal gas can be calculated by using the
Vf
expression w = − ∫ pex dV . The work can also be calculated from the pV– plot
Vi
no
by using the area under the curve within the specified limits. When an ideal
gas is compressed (a) reversibly or (b) irreversibly from volume Vi to Vf . choose
the correct option.
(i)
w (reversible) = w (irreversible)
(ii)
w (reversible) < w (irreversible)
(iii)
w (reversible) > w (irreversible)
(iv)
w (reversible) = w (irreversible) + pex.ΔV
69
Thermodynamics
9. The entropy change can be calculated by using the expression ΔS =
qrev
.
T
When water freezes in a glass beaker, choose the correct statement amongst
the following :
(i)
ΔS (system) decreases but ΔS (surroundings) remains the same.
(ii)
ΔS (system) increases but ΔS (surroundings) decreases.
(iii)
ΔS (system) decreases but ΔS (surroundings) increases.
(iv)
ΔS (system) decreases and ΔS (surroundings) also decreases.
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10. On the basis of thermochemical equations (a), (b) and (c), find out which of the
algebric relationships given in options (i) to (iv) is correct.
(a)
C (graphite) + O2 (g) ⎯→ CO2 (g) ; Δ rH = x kJ mol–1
(b)
C (graphite) +
(c)
CO (g) +
(i)
z=x+ y
(ii)
x=y –z
(iii)
x= y +z
(iv)
y = 2z – x
1
–1
O (g) ⎯→ CO (g) ; Δr H = y kJ mol
2 2
1
O (g) ⎯→ CO2 (g) ; Δr H = z kJ mol –1
2 2
11. Consider the reactions given below. On the basis of these reactions find out
which of the algebric relations given in options (i) to (iv) is correct?
(a)
C (g) + 4 H (g) ⎯→ CH4 (g); Δr H = x kJ mol–1
(b)
C (graphite,s) + 2H2 (g) ⎯→ CH4 (g); Δr H = y kJ mol–1
(i)
x= y
(ii)
x = 2y
(iii)
x> y
(iv)
x< y
no
12. The enthalpies of elements in their standard states are taken as zero. The
enthalpy of formation of a compound
(i)
is always negative
(ii)
is always positive
(iii)
may be positive or negative
(iv)
is never negative
Exemplar Problems, Chemistry
70
13. Enthalpy of sublimation of a substance is equal to
(i)
enthalpy of fusion + enthalpy of vapourisation
(ii)
enthalpy of fusion
(iii)
enthalpy of vapourisation
(iv)
twice the enthalpy of vapourisation
14. Which of the following is not correct?
(i)
ΔG is zero for a reversible reaction
(ii)
ΔG is positive for a spontaneous reaction
(iii)
ΔG is negative for a spontaneous reaction
ΔG is positive for a non-spontaneous reaction
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(iv)
II. Multiple Choice Questions (Type-II)
In the following questions two or more options may be correct.
15. Thermodynamics mainly deals with
(i)
interrelation of various forms of energy and their transformation from
one form to another.
(ii)
energy changes in the processes which depend only on initial and final
states of the microscopic systems containing a few molecules.
(iii)
how and at what rate these energy transformations are carried out.
(iv)
the system in equilibrium state or moving from one equilibrium state to
another equilibrium state.
16. In an exothermic reaction, heat is evolved, and system loses heat to the
surrounding. For such system
(i)
qp will be negative
(ii)
Δ rH will be negative
(iii)
qp will be positive
(iv)
Δ rH will be positive
17. The spontaneity means, having the potential to proceed without the assistance
of external agency. The processes which occur spontaneously are
flow of heat from colder to warmer body.
no
(i)
(ii)
gas in a container contracting into one corner.
(iii)
gas expanding to fill the available volume.
(iv)
burning carbon in oxygen to give carbon dioxide.
18. For an ideal gas, the work of reversible expansion under isothermal condition
Vf
can be calculated by using the expression w = – nRT ln V
i
71
Thermodynamics
A sample containing 1.0 mol of an ideal gas is expanded isothermally and
reversibly to ten times of its original volume, in two separate experiments.
The expansion is carried out at 300 K and at 600 K respectively. Choose the
correct option.
(i)
Work done at 600 K is 20 times the work done at 300 K.
(ii)
Work done at 300 K is twice the work done at 600 K.
(iii)
Work done at 600 K is twice the work done at 300 K.
(iv)
ΔU = 0 in both cases.
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19. Consider the following reaction between zinc and oxygen and choose the correct
options out of the options given below :
2 Zn (s) + O2 (g) ⎯→ 2 ZnO (s) ;
ΔH = – 693.8 kJ mol–1
(i)
The enthalpy of two moles of ZnO is less than the total enthalpy of two
moles of Zn and one mole of oxygen by 693.8 kJ.
(ii)
The enthalpy of two moles of ZnO is more than the total enthalpy of two
moles of Zn and one mole of oxygen by 693.8 kJ.
(iii)
693.8 kJ mol–1 energy is evolved in the reaction.
(iv)
693.8 kJ mol–1 energy is absorbed in the reaction.
III. Short Answer Type
20. 18.0 g of water completely vapourises at 100°C and 1 bar pressure and the
–1
enthalpy change in the process is 40.79 kJ mol . What will be the enthalpy
change for vapourising two moles of water under the same conditions? What
is the standard enthalphy of vapourisation for water?
21. One mole of acetone requires less heat to vapourise than 1 mol of water. Which
of the two liquids has higher enthalpy of vapourisation?
V
22. Standard molar enthalpy of formation, Δf H is just a special case of enthalpy
of reaction, Δ r HV. Is the Δr H V for the following reaction same as Δf HV? Give
reason for your answer.
CaO(s) + CO2(g) → CaCO3(s);
V
Δ f H = –178.3 kJ mol
–1
23. The value of Δf HV for NH3 is – 91.8 kJ mol–1. Calculate enthalpy change for the
following reaction :
no
2NH3(g) → N2(g) + 3H2(g)
24. Enthalpy is an extensive property. In general, if enthalpy of an overall reaction
A→B along one route is Δ r H and Δr H 1, Δ rH 2, Δ r H3 ..... represent enthalpies of
intermediate reactions leading to product B. What will be the relation between
Δ r H for overall reaction and Δr H1 , Δr H2 ..... etc. for intermediate reactions.
25. The enthalpy of atomisation for the reaction CH4(g)→ C(g) + 4H (g) is
1665 kJ mol–1. What is the bond energy of C–H bond?
Exemplar Problems, Chemistry
72
26. Use the following data to calculate Δ lattice HV for NaBr.
Δsub HV for sodium metal = 108.4 kJ mol–1
–1
Ionization enthalpy of sodium = 496 kJ mol
Electron gain enthalpy of bromine = – 325 kJ mol–1
Bond dissociation enthalpy of bromine = 192 kJ mol–1
Δf HV for NaBr (s) = – 360.1 kJ mol–1
27. Given that ΔH = 0 for mixing of two gases. Explain whether the diffusion of these
gases into each other in a closed container is a spontaneous process or not?
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28. Heat has randomising influence on a system and temperature is the measure
of average chaotic motion of particles in the system. Write the mathematical
relation which relates these three parameters.
29. Increase in enthalpy of the surroundings is equal to decrease in enthalpy of
the system. Will the temperature of system and surroundings be the same
when they are in thermal equilibrium?
30. At 298 K. Kp for the reaction N2O4 (g) U 2NO2 (g) is 0.98. Predict whether the
reaction is spontaneous or not.
31. A sample of 1.0 mol of a monoatomic ideal gas is taken through a cyclic
process of expansion and compression as shown in Fig. 6.1. What will be the
value of ΔH for the cycle as a whole?
Fig. : 6.1
no
32. The standard molar entropy of H2O (l ) is 70 J K –1 mol–1. Will the standard
molar entropy of H 2O(s) be more, or less than 70 J K–1 mol–1?
33. Identify the state functions and path functions out of the following :
enthalpy, entropy, heat, temperature, work, free energy.
34. The molar enthalpy of vapourisation of acetone is less than that of water. Why?
35. Which quantity out of Δ rG and ΔrG V will be zero at equilibrium?
36. Predict the change in internal energy for an isolated system at constant volume.
73
Thermodynamics
37. Although heat is a path function but heat absorbed by the system under
certain specific conditions is independent of path. What are those conditions?
Explain.
38. Expansion of a gas in vacuum is called free expansion. Calculate the work
done and the change in internal energy when 1 litre of ideal gas expands
isothermally into vacuum until its total volume is 5 litre?
39. Heat capacity (Cp ) is an extensive property but specific heat (c) is an intensive
property. What will be the relation between C p and c for 1 mol of water?
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40. The difference between CP and C V can be derived using the empirical relation
H = U + pV. Calculate the difference between CP and CV for 10 moles of an ideal gas.
41. If the combustion of 1g of graphite produces 20.7 kJ of heat, what will be
molar enthalpy change? Give the significance of sign also.
42. The net enthalpy change of a reaction is the amount of energy required to
break all the bonds in reactant molecules minus amount of energy required
to form all the bonds in the product molecules. What will be the enthalpy
change for the following reaction.
H 2(g) + Br2(g) → 2HBr(g)
–1
–1
Given that Bond energy of H2, Br2 and HBr is 435 kJ mol , 192 kJ mol and
368 kJ mol –1 respectively.
–1
43. The enthalpy of vapourisation of CCl 4 is 30.5 kJ mol . Calculate the heat
required for the vapourisation of 284 g of CCl 4 at constant pressure. (Molar
mass of CCl 4 = 154 g mol –1).
44. The enthalpy of reaction for the reaction :
2H2(g) + O 2(g) → 2H2O(l) is Δr HV = – 572 kJ mol–1.
What will be standard enthalpy of formation of
H 2O (l ) ?
45. What will be the work done on an ideal gas enclosed
in a cylinder, when it is compressed by a constant
external pressure, p ext in a single step as shown in
Fig. 6.2. Explain graphically.
46. How will you calculate work done on an ideal gas
in a compression, when change in pressure is
carried out in infinite steps?
no
Fig. : 6.2
47. Represent the potential energy/enthalpy change in
the following processes graphically.
(a)
Throwing a stone from the ground to roof.
(b)
1
1
H (g) +
Cl (g) U HCl(g)
2 2
2 2
ΔrH V= –92.32 kJ mol–1
In which of the processes potential energy/enthalpy change is contributing
factor to the spontaneity?
Exemplar Problems, Chemistry
74
48. Enthalpy diagram for a particular reaction is
given in Fig. 6.3. Is it possible to decide
spontaneity of a reaction from given diagram.
Explain.
49. 1 . 0 m o l o f a m o no a t o m i c i d e a l g a s i s
expanded from state (1) to state (2) as shown in
Fig. 6.4. Calculate the work done for the expansion
of gas from state (1) to state (2) at 298 K.
Fig. : 6.3
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50. An ideal gas is allowed to expand against a
constant pressure of 2 bar from 10 L to 50 L in
one step. Calculate the amount of work done by
the gas. If the same expansion were carried out
reversibly, will the work done be higher or lower
than the earlier case?
(Given that 1 L bar = 100 J)
IV. Matching Type
Fig. : 6.4
In the following questions more than one correlation is possible between
options of both columns.
51. Match the following :
A
B
Adiabatic process
(a) Heat
(ii)
Isolated system
(b) At constant volume
(iii)
Isothermal change
(c) First law of thermodynamics
(iv)
Path function
(d) No exchange of energy and matter
(v)
State function
(e) No transfer of heat
(vi)
ΔU = q
(f)
(vii)
Law of conservation of energy
(g) Internal energy
(viii)
Reversible process
(h) pext = 0
(ix)
Free expansion
(i)
At constant pressure
(x)
ΔH = q
(j)
Infinitely slow process which
proceeds through a series of
equilibrium states.
(xi)
Intensive property
(k) Entropy
(xii)
Extensive property
(l)
no
(i)
Constant temperature
Pressure
(m) Specific heat
75
Thermodynamics
52. Match the following processes with entropy change:
Reaction
Entropy change
(i)
A liquid vapourises
(a) ΔS = 0
(ii)
Reaction is non-spontaneous
at all temperatures and ΔH
is positive
(b) ΔS = positive
(iii)
Reversible expansion of an
(c) ΔS = negative
ideal gas
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53. Match the following parameters with description for spontaneity :
Δ (Parameters)
Δ r HV
Δ r SV
Δ r GV
(i)
+
–
+
(ii)
–
–
+ at high T
(iii)
–
+
–
Description
(a) Non-spontaneous at high
temperature.
(b) Spontaneous at all temperatures
(c) Non-spontaneous at all
temperatures
54. Match the following :
(i) Entropy of vapourisation
(a)
decreases
(ii) K for spontaneous process
(b)
is always positive
(iii) Crystalline solid state
(c)
lowest entropy
(iv) ΔU in adiabatic expansion
(d)
ΔH vap
Tb
of ideal gas
V. Assertion and Reason Type
In the following questions a statement of Assertion (A) followed by a statement
of Reason (R) is given. Choose the correct option out of the choices given
below each question.
no
55. Assertion (A): Combustion of all organic compounds is an exothermic
reaction.
Reason (R) :
The enthalpies of all elements in their standard state are zero.
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
A is false but R is true.
Exemplar Problems, Chemistry
76
56. Assertion (A) : Spontaneous process is an irreversible process and may be
reversed by some external agency.
Reason (R) :
Decrease in enthalpy is a contributory factor for spontaneity.
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
A is false but R is true.
57. Assertion (A) : A liquid crystallises into a solid and is accompanied by
decrease in entropy.
In crystals, molecules organise in an ordered manner.
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Reason (R) :
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
A is false but R is true.
VI. Long Answer Type
58. Derive the relationship between ΔH and ΔU for an ideal gas. Explain each
term involved in the equation.
59. Extensive properties depend on the quantity of matter but intensive properties
do not. Explain whether the following properties are extensive or intensive.
Mass, internal energy, pressure, heat capacity, molar heat capacity, density,
mole fraction, specific heat, temperature and molarity.
60. The lattice enthalpy of an ionic compound is the enthalpy when one mole of
an ionic compound present in its gaseous state, dissociates into its ions. It is
impossible to determine it directly by experiment. Suggest and explain an
indirect method to measure lattice enthalpy of NaCl(s).
61. ΔG is net energy available to do useful work and is thus a measure of “free
energy”. Show mathematically that ΔG is a measure of free energy. Find the
unit of ΔG. If a reaction has positive enthalpy change and positive entropy
change, under what condition will the reaction be spontaneous?
no
62. Graphically show the total work done in an expansion when the state of an
ideal gas is changed reversibly and isothermally from (pi , Vi ) to (pf , Vf ). With
the help of a pV plot compare the work done in the above case with that
carried out against a constant external pressure pf .
77
Thermodynamics
ANSWERS
I. Multiple Choice Questions (Type-I)
1. (iii)
2. (iii)
3. (iv)
4. (iii)
5. (iii)
6. (ii)
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7. (iii)
Justification : free expansion
w=0
adiabatic process q = 0
ΔU = q + w = 0, this means that internal energy remains
constant. Therefore, ΔT = 0.
In ideal gas there is no intermolecular attraction. Hence when such a gas
expands under adiabatic conditions into a vaccum no heat is absorbed or
evolved since no external work is done to separate the molecules.
8. (ii) w (reversible) < w (irreversible)
Justification : Area under the curve is always more in irreversible
compression as can be seen from Fig. 6.5 (a) and (b).
(a) Reversible compression
(b) Irreversible compression
Fig. : 6.5
9. (iii)
Justification : Freezing is exothermic process. The heat released increases
the entropy of surrounding.
no
10. (iii)
11. (iii)
Justification : Same bonds are formed in reaction (a) and (b) but bonds
between reactant molecules are broken only in reaction (b).
12. (iii)
13. (i)
Exemplar Problems, Chemistry
14. (ii)
78
II. Multiple Choice Questions (Type-II)
15. (i), (iv)
16. (i), (ii)
17. (iii), (iv)
18. (iii), (iv)
w 600K
Justification : w 300K
10
1 = 600 = 2
=
10
300
1 × R × 300 K ln
1
1 × R × 600 K ln
For isothermal expansion of ideal gases, ΔU = 0
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since temperature is constant this means there is no change in internal energy.
Therefore, ΔU = 0
19. (i), (iii)
III. Short Answer Type
V
20.
+ 81.58 kJ, ΔvapH = + 40.79 kJ mol
21.
Water
22.
No, since CaCO3 has been formed from other compounds and not from its
constituent elements.
23.
Δr H
24.
Δ r H = Δr H 1+ Δ r H2 + Δ r H3 .....
25.
1665
–1
–1
kJ mol = 416.2 kJ mol
4
26.
+735.5 kJ mol –1
27.
It is spontaneous process. Although enthalpy change is zero but
randomness or disorder (i.e., ΔS ) increases. Therefore, in equation
ΔG = ΔH – TΔS, the term TΔS will be negative. Hence, ΔG will be negative.
28.
ΔS =
29.
Yes
30.
The reaction is spontaneous
= +91.8 kJ mol–1
qrev
T
no
V
–1
V
Δ r G = – RT ln K p
31.
ΔH (cycle) = 0
32.
Less, because ice is more ordered than H 2O (l ).
33.
State Functions : Enthalpy, Entropy, Temperature, Free energy
Path Functions : Heat, Work
79
Thermodynamics
34.
Because of strong hydrogen bonding in water, its enthalpy of
vapourisation is more.
35.
Δr G will always be zero.
V
V
V
Δr G is zero for K = 1 because ΔG = – RT lnK, ΔG will be non zero for
other values of K.
36.
For isolated system, there is no transfer of energy as heat or as work i.e.,
w=0 and q=0. According to the first law of thermodynamics.
ΔU = q + w
= 0+0=0
ΔU = 0
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∴
37.
At constant volume
By first law of thermodynamics:
q = ΔU + (–w)
(–w) = pΔV
∴
q = ΔU + pΔV
ΔV = 0, since volume is constant.
∴ qV = ΔU + 0
⇒ qV = ΔU = change in internal energy
At constant pressure
qp = ΔU + pΔV
But, ΔU + pΔV = ΔH
∴
qp = ΔH = change in enthalpy.
So, at a constant volume and at constant pressure heat change is a state
function because it is equal to change in internal energy and change in
enthalpy respectively which are state functions.
38.
(–w) = pext (V2–V 1) = 0 × (5 – 1) = 0
For isothermal expansion q = 0
By first law of thermodynamics
q = ΔU + (–w)
⇒ 0 = ΔU + 0 so ΔU = 0
For water, heat capacity = 18 × specific heat
no
39.
or
Cp = 18 × c
–1
Specific heat = c = 4.18 Jg K
–1
Heat capacity = Cp = 18 × 4.18 JK–1 = 75.3 J K –1
40.
CP – C V = nR
= 10 × 4.184 J
Exemplar Problems, Chemistry
80
41.
Molar enthalpy
= enthalpy change for 1 g carbon × molar mass of carbon
change of graphite
–1
–1
= – 20.7 kJ g × 12g mol
∴ ΔH = – 2.48 × 10 2 kJ mol–1
Negative value of ΔH ⇒ exothermic reaction.
42.
V
Δ rH = Bond energy of H2 + Bond energy of Br2 – 2 × Bond energy of HBr
–1
= 435 + 192 – (2 × 368) kJ mol
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⇒ Δ rHV = –109 kJ mol–1
43.
qp = ΔH = 30.5 kJ mol–1
∴ Heat required for vapourisation of 284 g of CCl4 =
284g
154g mol
–1
× 30.5 kJ mol–1
= 56.2 kJ
44.
According to the definition of standard enthalpy of formation, the enthalpy
change for the following reaction will be standard enthalpy of formation
of H 2O (l)
H 2(g) +
1
O (g) → H2O(l ).
2 2
or the standard enthalpy of formation of H2O(l ) will be half of the enthalpy
V
of the given equation i.e., Δr H is also halved.
V
Δ f H H O(l ) =
2
Work done on an ideal gas can be calculated from p-V graph shown in
Fig. 6.6. Work done is equal to the shaded area ABVIVII .
no
45.
–1
1
− 572 kJ mol
V
× Δr H =
= – 286 kJ/mol.
2
2
Fig. : 6.6
81
Thermodynamics
The work done can be calculated with the help of p–V plot. A p–V plot of
the work of compression which is carried out by change in pressure in
infinite steps, is given in Fig. 6.7. Shaded area represents the work done
on the gas.
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46.
Fig. : 6.7
47.
Fig. : 6.8 Enthalpy change in processes (a) and (b)
48.
No.
Enthalpy is one of the contributory factors in deciding spontaneity but it
is not the only factor. One must look for contribution of another factor
i.e., entropy also, for getting the correct result.
It is clear from the figure that the process has been carried out in infinite
steps, hence it is isothermal reversible expansion.
no
49.
V2
w = – 2.303nRT log V
1
But, p1V 1 = p2V2
Exemplar Problems, Chemistry
V2
p1
2
⇒ V = p =
=2
1
1
2
82
p1
w = – 2.303 nRT log p
2
∴
= – 2.303 × 1 mol × 8.314 J mol–1 K –1 × 298 K–1 × log 2
= – 2.303 × 8.314 × 298 × 0.3010 J = –1717.46 J
50.
w = – p ex (Vf –Vi ) = –2 × 40 = – 80 L bar = – 8 kJ
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The negative sign shows that work is done by the system on the
surrounding. Work done will be more in the reversible expansion because
internal pressure and exernal pressure are almost same at every step.
IV. Matching Type
(i) → (e)
(ii) → (d)
(iii) → (f)
(iv) → (a)
(v) → (g), (k), (l)
(vi) → (b)
(vii) → (c)
(viii) → (j)
(ix) → (h)
(x) → (i)
(xi) → (a), (l), (m)
(xii) → (g), (k)
52.
(i) →(b)
(ii) → (c)
(iii) → (a)
53.
(i) → (c)
(ii) → (a)
(iii) → (b)
54.
(i) → (b), (d)
(ii) → (b)
(iii) → (c)
51.
(iv) → (a)
V. Assertion and Reason Type
55. (ii)
56. (ii)
57. (i)
VI. Long Answer Type
59.
Hint : Ratio of two extensive properties is always intensive
Extensive
= Intensive .
Extensive
no
e.g., Mole fraction =
60.
• Na (s) +
Moles
(Extensive)
=
Total number of moles
(Extensive)
1
Cl 2 (g) → Na+ (g) + Cl–(g) ;
2
V
ΔlatticeH
83
Thermodynamics
• Bonn - Haber Cycle
• Steps to measure lattice enthalpy from Bonn - Haber cycle
• Sublimation of sodium metal
V
(1) Na(s) → Na (g) ;
Δsub H
(2) Ionisation of sodium atoms
V
Na(g) → Na+ (g) + e–(g) ;
ΔtH
i.e., ionisation enthalpy
(3) Dissociation of chlorine molecule
1
Δ
HV
2 bond
i.e., One-half of bond dissociation
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1
Cl (g) → Cl(g) ;
2 2
enthalpy.
(4) Cl(g) + e–(g) → Cl–(g) ;
Δeg HV
i.e., electron gain enthalpy.
+
Na (g) + Cl (g)
1
Δ HV
2 bond
1
Na+(g) + Cl2(g)
2
V
ΔegH
Na+ (g) + Cl–(g)
Δ iH V
Na(g) +
1
Cl (g)
2 2
V
Δ latticeH
ΔsubHV
Na(s) +
1
Cl (g)
2 2
Δf H
V
NaCl(s)
ΔSTotal
= ΔSsys + ΔSsurr
ΔSTotal
⎛ -ΔH sys ⎞
= ΔSsys + ⎜ T ⎟
⎝
⎠
no
61.
T ΔSTotal = T ΔSsys – ΔHsys
For spontaneous change, ΔStotal > 0
∴
T Δ Ssys – ΔHsys > 0
⇒
– (ΔHsys – T Δ Ssys ) > 0
Exemplar Problems, Chemistry
84
But, ΔHsys – T Δ Ssys = ΔGsys
∴
– ΔGsys > 0
⇒
ΔGsys = ΔH sys – T ΔSsys < 0
ΔHsys= Enthalpy change of a reaction.
T ΔSsys = Energy which is not available to do useful work.
ΔGsys = Energy available for doing useful work.
• Unit of ΔG is Joule
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• The reaction will be spontaneous at high temperature.
62.
Fig. : 6.9
.
no
(i) Reversible Work is represented by the combined areas
and
(ii) Work against constant pressure, p f is represented by the area
Work (i) > Work (ii)
85
Thermodynamics
Unit
7
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EQUILIBRIUM
I. Multiple Choice Questions (Type-I)
1.
We know that the relationship between Kc and Kp is
K p = Kc (RT)
Δn
What would be the value of Δn for the reaction
NH 4Cl (s) U NH3 (g) + HCl (g)
2.
1
(ii)
0.5
(iii)
1.5
(iv)
2
V
For the reaction H2(g) + I2(g) U 2HI (g), the standard free energy is ΔG > 0.
The equilibrium constant (K ) would be __________.
(i)
K=0
(ii)
K>1
(iii)
K=1
(iv)
K<1
Which of the following is not a general characteristic of equilibria involving
physical processes?
no
3.
(i)
(i)
Equilibrium is possible only in a closed system at a given temperature.
(ii)
All measurable properties of the system remain constant.
(iii)
All the physical processes stop at equilibrium.
(iv)
The opposing processes occur at the same rate and there is dynamic
but stable condition.
5.
6.
PCl5, PCl3 and Cl2 are at equilibrium at 500K in a closed container and their
concentrations are 0.8 × 10–3 mol L–1, 1.2 × 10 –3 mol L–1 and 1.2 × 10–3 mol L–1
respectively. The value of Kc for the reaction PCl5 (g) U PCl3 (g) + Cl2 (g)
will be
3
1.8 × 10 mol L
(ii)
1.8 × 10–3
(iii)
1.8 × 10 L mol
(iv)
0.55 × 104
–3
–1
Which of the following statements is incorrect?
(i)
In equilibrium mixture of ice and water kept in perfectly insulated flask
mass of ice and water does not change with time.
(ii)
The intensity of red colour increases when oxalic acid is added to a
solution containing iron (III) nitrate and potassium thiocyanate.
(iii)
On addition of catalyst the equilibrium constant value is not affected.
(iv)
Equilibrium constant for a reaction with negative ΔH value decreases
as the temperature increases.
When hydrochloric acid is added to cobalt nitrate solution at room
temperature, the following reaction takes place and the reaction mixture
becomes blue. On cooling the mixture it becomes pink. On the basis of this
information mark the correct answer.
3+
[Co (H2O)6]
(pink)
–
2–
(aq) + 4Cl (aq) U [CoCl4] (aq) + 6H2O (l )
(blue)
(i)
ΔH > 0 for the reaction
(ii)
ΔH < 0 for the reaction
(iii)
ΔH = 0 for the reaction
(iv)
The sign of ΔH cannot be predicted on the basis of this information.
The pH of neutral water at 25°C is 7.0. As the temperature increases, ionisation
of water increases, however, the concentration of H+ ions and OH– ions are
equal. What will be the pH of pure water at 60°C?
(i)
Equal to 7.0
(ii)
Greater than 7.0
(iii)
Less than 7.0
(iv)
Equal to zero
no
7.
–1
(i)
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4.
8.
The ionisation constant of an acid, Ka , is the measure of strength of an acid.
The K a values of acetic acid, hypochlorous acid and formic acid are
1.74 × 10–5, 3.0 × 10–8 and 1.8 × 10–4 respectively. Which of the following
orders of pH of 0.1 mol dm–3 solutions of these acids is correct?
(i)
acetic acid > hypochlorous acid > formic acid
(ii)
hypochlorous acid > acetic acid > formic acid
87
Equilibrium
9.
(iii)
formic acid > hypochlorous acid > acetic acid
(iv)
formic acid > acetic acid > hypochlorous acid
K a , K a and K a are the respective ionisation constants for the following
1
2
3
reactions.
H2S U H+ + HS–
–
+
2–
HS U H + S
H2S U 2H+ + S2–
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The correct relationship between Ka1 , K a 2 and K a3 is
(i)
Ka = Ka × Ka
3
1
2
(ii)
Ka = Ka + Ka
3
1
2
(iii)
K a = Ka – K a
3
1
2
(iv)
Ka = Ka / Ka
3
1
2
10. Acidity of BF3 can be explained on the basis of which of the following concepts?
(i)
Arrhenius concept
(ii)
Bronsted Lowry concept
(iii)
Lewis concept
(iv)
Bronsted Lowry as well as Lewis concept.
11. Which of the following will produce a buffer solution when mixed in equal
volumes?
(i)
0.1 mol dm–3 NH4OH and 0.1 mol dm–3 HCl
(ii)
0.05 mol dm–3 NH4OH and 0.1 mol dm–3 HCl
(iii)
0.1 mol dm–3 NH4OH and 0.05 mol dm–3 HCl
(iv)
0.1 mol dm–3 CH4COONa and 0.1 mol dm–3 NaOH
12. In which of the following solvents is silver chloride most soluble?
0.1 mol dm–3 AgNO3 solution
(ii)
0.1 mol dm–3 HCl solution
no
(i)
(iii)
H2O
(iv)
Aqueous ammonia
–5
13. What will be the value of pH of 0.01 mol dm–3 CH3COOH (Ka = 1.74 × 10 )?
(i)
3.4
(ii)
3.6
Exemplar Problems, Chemistry
88
(iii)
3.9
(iv)
3.0
–5
14. K a for CH3COOH is 1.8 × 10
ammonium acetate will be
(i)
7.005
(ii)
4.75
(iii)
7.0
(iv)
Between 6 and 7
–5
and K b for NH4OH is 1.8 × 10
. The pH of
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15. Which of the following options will be correct for the stage of half completion
of the reaction A U B.
(i)
ΔGV = 0
(ii)
ΔG > 0
(iii)
ΔGV < 0
(iv)
ΔGV = –RT ln2
V
16. On increasing the pressure, in which direction will the gas phase reaction
proceed to re-establish equilibrium, is predicted by applying the Le Chatelier’s
principle. Consider the reaction.
N2 (g) + 3H2 (g) U 2NH3 (g)
Which of the following is correct, if the total pressure at which the equilibrium
is established, is increased without changing the temperature?
(i)
K will remain same
(ii)
K will decrease
(iii)
K will increase
(iv)
K will increase initially and decrease when pressure is very high
17. What will be the correct order of vapour pressure of water, acetone and ether
at 30°C. Given that among these compounds, water has maximum boiling
point and ether has minimum boiling point?
Water < ether < acetone
(ii)
Water < acetone < ether
(iii)
Ether < acetone < water
(iv)
Acetone < ether < water
no
(i)
18. At 500 K, equilibrium constant, K c , for the following reaction is 5.
1
1
H2 (g) +
I (g) U HI (g)
2
2 2
What would be the equilibrium constant Kc for the reaction
2HI (g) U H 2 (g) + I2 (g)
89
Equilibrium
(i)
0.04
(ii)
0.4
(iii)
25
(iv)
2.5
19. In which of the following reactions, the equilibrium remains unaffected on
addition of small amount of argon at constant volume?
H 2 (g) + I2 (g) U 2HI (g)
(ii)
PCl 5 (g) U PCl3 (g) + Cl2 (g)
(iii)
N2 (g) + 3H2 (g) U 2NH3 (g)
(iv)
The equilibrium will remain unaffected in all the three cases.
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(i)
II. Multiple Choice Questions (Type-II)
In the following questions two or more options may be correct.
20. For the reaction N2O4 (g) U 2NO2 (g), the value of K is 50 at 400 K and 1700
at 500 K. Which of the following options is correct?
(i)
The reaction is endothermic
(ii)
The reaction is exothermic
(iii)
If NO2 (g) and N2O4 (g) are mixed at 400 K at partial pressures 20 bar
and 2 bar respectively, more N2O4 (g) will be formed.
(iv)
The entropy of the system increases.
21. At a particular temperature and atmospheric pressure, the solid and liquid
phases of a pure substance can exist in equilibrium. Which of the following
term defines this temperature?
(i)
Normal melting point
(ii)
Equilibrium temperature
(iii)
Boiling point
(iv)
Freezing point
no
III. Short Answer Type
22. The ionisation of hydrochloric in water is given below:
+
–
HCl(aq) + H2O (l ) U H3O (aq) + Cl (aq)
Label two conjugate acid-base pairs in this ionisation.
23. The aqueous solution of sugar does not conduct electricity. However, when
sodium chloride is added to water, it conducts electricity. How will you explain
this statement on the basis of ionisation and how is it affected by concentration
of sodium chloride?
Exemplar Problems, Chemistry
90
24. BF3 does not have proton but still acts as an acid and reacts with NH3. Why is
it so? What type of bond is formed between the two?
25. Ionisation constant of a weak base MOH, is given by the expression
+
Kb =
–
[M ][OH ]
[MOH]
Values of ionisation constant of some weak bases at a particular temperature
are given below:
Dimethylamine
Urea
Pyridine
Ammonia
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Base
Kb
5.4 × 10
–4
–14
1.3 × 10
1.77 × 10
–9
1.77 × 10
–5
Arrange the bases in decreasing order of the extent of their ionisation at
equilibrium. Which of the above base is the strongest?
26. Conjugate acid of a weak base is always stronger. What will be the decreasing
order of basic strength of the following conjugate bases?
–
–
–
–
OH , RO , CH3COO , Cl
27. Arrange the following in increasing order of pH.
KNO3 (aq), CH3COONa (aq), NH4Cl (aq), C6H 5COONH4 (aq)
28. The value of K c for the reaction 2HI (g) U H2 (g) + I2 (g) is 1 × 10–4
At a given time, the composition of reaction mixture is
–5
[HI] = 2 × 10 mol,
–5
–5
[H2] = 1 × 10 mol and [I2] = 1 × 10 mol
In which direction will the reaction proceed?
+
–8
29. On the basis of the equation pH = – log [H ], the pH of 10 mol dm–3 solution
of HCl should be 8. However, it is observed to be less than 7.0. Explain the
reason.
30. pH of a solution of a strong acid is 5.0. What will be the pH of the solution
obtained after diluting the given solution a 100 times?
no
31. A sparingly soluble salt gets precipitated only when the product of
concentration of its ions in the solution (Qsp) becomes greater than its solubility
product. If the solubility of BaSO4 in water is 8 × 10–4 mol dm–3. Calculate its
solubility in 0.01 mol dm–3 of H2SO4.
32. pH of 0.08 mol dm–3 HOCl solution is 2.85. Calculate its ionisation constant.
33. Calculate the pH of a solution formed by mixing equal volumes of two solutions
A and B of a strong acid having pH = 6 and pH = 4 respectively.
34. The solubility product of Al (OH)3 is 2.7 × 10 –11. Calculate its solubility in gL–1
and also find out pH of this solution. (Atomic mass of Al = 27 u).
91
Equilibrium
35. Calculate the volume of water required to dissolve 0.1 g lead (II) chloride to
get a saturated solution. (Ksp of PbCl2 = 3.2 × 10–8 , atomic mass of Pb = 207 u).
36. A reaction between ammonia and boron trifluoride is given below:
: NH3 + BF3 ⎯→ H3N : BF 3
Identify the acid and base in this reaction. Which theory explains it? What is
the hybridisation of B and N in the reactants?
37. Following data is given for the reaction: CaCO3 (s) → CaO (s) + CO2 (g)
V
Δf H [CaO(s)] = – 635.1 kJ mol
–1
Δf HV [CO2(g)] = – 393.5 kJ mol–1
V
Δf H [CaCO3(s)] = – 1206.9 kJ mol
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–1
Predict the effect of temperature on the equilibrium constant of the above
reaction.
IV. Matching Type
38. Match the following equilibria with the corresponding condition
(i) Liquid U Vapour
(a)
Saturated solution
(ii) Solid U Liquid
(b)
Boiling point
(iii) Solid U Vapour
(c)
Sublimation point
(iv) Solute (s) U Solute (solution)
(d)
Melting point
(e)
Unsaturated solution
39. For the reaction : N2 (g) + 3H2(g) U 2NH 3(g)
2
Equilibrium constant K c =
[NH 3 ]
3
[N 2 ][H 2 ]
Some reactions are written below in Column I and their equilibrium constants
in terms of Kc are written in Column II. Match the following reactions with the
corresponding equilibrium constant
Column I (Reaction)
2N2(g) + 6H2(g) U 4NH3(g)
no
(i)
Column II (Equilibrium constant)
(a)
2K c
1
(ii)
2NH3(g) U N2(g) + 3H2(g)
(b)
K c2
(iii)
1
3
N2(g) + H 2(g) U NH3(g)
2
2
(c)
1
Kc
(d)
Kc2
Exemplar Problems, Chemistry
92
40. Match standard free energy of the reaction with the corresponding equilibrium
constant
V
(i)
ΔG >0
(a)
K>1
(ii)
V
(b)
K=1
(c)
K=0
(d)
K<1
(iii)
ΔG <0
V
ΔG =0
41. Match the following species with the corresponding conjugate acid
Species
Conjugate acid
(a)
CO32–
HCO3
(b)
NH4
(iii)
H2O
(c)
H3O
(iv)
HSO4–
(d)
H2SO4
(e)
H2CO3
NH3
(ii)
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(i)
–
+
+
42. Match the following graphical variation with their description
A
B
(a) Variation in product concentration
with time
(ii)
(b) Reaction at equilibrium
no
(i)
(iii)
(c) Variation in reactant concentration
with time
93
Equilibrium
43. Match Column (I) with Column (II).
Column I
Column II
(i)
Equilibrium
(a)
ΔG > 0, K < 1
(ii)
Spontaneous reaction
(b)
ΔG = 0
(iii)
Non spontaneous reaction
(c)
ΔG = 0
(d)
ΔG < 0, K > 1
V
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V. Assertion and Reason Type
In the following questions a statement of Assertion (A) followed by a statement
of Reason (R) is given. Choose the correct option out of the choices given
below each question.
44. Assertion (A) : Increasing order of acidity of hydrogen halides is
HF < HCl < HBr < HI
Reason (R) :
While comparing acids formed by the elements belonging to
the same group of periodic table, H–A bond strength is a more
important factor in determining acidity of an acid than the
polar nature of the bond.
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
Both A and R are false.
45. Assertion (A) : A solution containing a mixture of acetic acid and sodium
acetate maintains a constant value of pH on addition of small
amounts of acid or alkali.
Reason (R) :
A solution containing a mixture of acetic acid and sodium
acetate acts as a buffer solution around pH 4.75.
Both A and R are true and R is correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
Both A and R are false.
no
(i)
46. Assertion (A): The ionisation of hydrogen sulphide in water is low in the
presence of hydrochloric acid.
Reason (R) :
Hydrogen sulphide is a weak acid.
(i)
Both A and R are true and R is correct explanation of A.
(ii)
Both A and R are true but R is not correct explanation of A.
Exemplar Problems, Chemistry
94
(iii)
A is true but R is false
(iv)
Both A and R are false
47. Assertion (A): For any chemical reaction at a particular temperature, the
equilibrium constant is fixed and is a characteristic property.
Reason (R) :
Equilibrium constant is independent of temperature.
Both A and R are true and R is correct explanation of A.
(ii)
Both A and R are true but R is not correct explanation of A.
(iii)
A is true but R is false.
(iv)
Both A and R are false.
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(i)
48. Assertion (A) : Aqueous solution of ammonium carbonate is basic.
Reason (R) :
Acidic/basic nature of a salt solution of a salt of weak acid
and weak base depends on K a and Kb value of the acid and
the base forming it.
(i)
Both A and R are true and R is correct explanation of A.
(ii)
Both A and R are true but R is not correct explanation of A.
(iii)
A is true but R is false.
(iv)
Both A and R are false.
49. Assertion (A): An aqueous solution of ammonium acetate can act as a
buffer.
Reason (R) :
Acetic acid is a weak acid and NH4OH is a weak base.
(i)
Both A and R are true and R is correct explanation of A.
(ii)
Both A and R are true but R is not correct explanation of A.
(iii)
A is false but R is true.
(iv)
Both A and R are false.
50. Assertion (A): In the dissociation of PCl5 at constant pressure and
temperature addition of helium at equilibrium increases the
dissociation of PCl5 .
Reason (R) :
Helium removes Cl2 from the field of action.
Both A and R are true and R is correct explanation of A.
(ii)
Both A and R are true but R is not correct explanation of A.
(iii)
A is true but R is false.
no
(i)
(iv)
Both A and R are false.
VI. Long Answer Type
51. How can you predict the following stages of a reaction by comparing the value
of K c and Qc?
(i)
Net reaction proceeds in the forward direction.
95
Equilibrium
(ii)
Net reaction proceeds in the backward direction.
(iii)
No net reaction occurs.
52. On the basis of Le Chatelier principle explain how temperature and pressure
can be adjusted to increase the yield of ammonia in the following reaction.
N2(g) + 3H2(g) U 2NH3(g)
Δ H = – 92.38 kJ mol–1
What will be the effect of addition of argon to the above reaction mixture at constant
volume?
p+
q−
53. A sparingly soluble salt having general formula A x B y and molar solubility
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S is in equilibrium with its saturated solution. Derive a relationship between
the solubility and solubility product for such salt.
54. Write a relation between ΔG and Q and define the meaning of each term and
answer the following :
(a) Why a reaction proceeds forward when Q < K and no net reaction occurs
when Q = K.
no
(b) Explain the effect of increase in pressure in terms of reaction quotient Q.
for the reaction : CO (g) + 3H2 (g) U CH4 (g) + H2O (g)
Exemplar Problems, Chemistry
96
ANSWERS
I. Multiple Choice Questions (Type-I)
1. (iv)
2. (iv)
3. (iii)
4. (ii)
5. (ii)
7. (iii)
8. (iv)
9. (i)
10. (iii)
11. (iii)
13. (i)
14. (iii)
15.
6. (i)
12. (iv)
V
(i) ΔG = 0
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Justification : ΔGV = – RT lnK
At the stage of half completion of reaction [A] = [B], Therefore, K = 1.
Thus, ΔGV = 0
16.
(i), Justification: According to Le-Chatelier’s principle, at constant
temperature, the equilibrium composition will change
but K will remain same.
17.
(ii)
18.
(i)
19.
(iv)
II. Multiple Choice Questions (Type-II)
20.
(i), (iii) and (iv)
Justification : (i)
21.
K increases with increase in temperature.
(iii)
Q > K, Therefore, reaction proceeds in the backward
direction.
(iv)
Δ n > 0, Therefore, Δ S > 0.
(i) and (iv)
III. Short Answer Type
HCl
Cl–
acid
conjugate base
H 2O
H3O
base
conjugate acid
no
22.
23.
+
•
Sugar does not ionise in water but NaCl ionises completely in water
and produces Na+ and Cl– ions.
•
Conductance increases with increase in concentration of salt due to
release of more ions.
97
Equilibrium
24.
BF3 acts as a Lewis acid as it is electron deficient compound and coordinate
bond is formed as given below :
H3N : → BF 3
25.
• Order of extent of ionisation at equilibrium is as follows :
Dimethylamine > Ammonia > Pyridine > Urea
• Since dimethylamine will ionise to the maximum extent it is the
strongest base out of the four given bases.
–
–
–
–
RO > OH > CH3COO > Cl
27.
NH4Cl < C6H5COONH4 < KNO3 < CH 3COONa
28.
At a given time the reaction quotient Q for the reaction will be given by the
expression.
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26.
Q =
=
[H 2 ][I 2 ]
2
[HI ]
1 × 10
–5
× 1 × 10
–5
=
(2 × 10 )
–5 2
= 0.25 = 2.5 × 10
1
4
–1
As the value of reaction quotient is greater than the value of Kc i.e. 1× 10–4
the reaction will proceed in the reverse direction.
29.
Concentration of 10–8 mol dm–3 indicates that the solution is very dilute.
Hence, the contribution of H3O + concentration from water is significant
and should also be included for the calculation of pH.
30.
(i) pH = 5
+
–5
–1
[H ] = 10 mol L
On 100 times dilution
[H+ ] = 10–7 mol L–1
+
On calculating the pH using the equation pH = – log [H ], value of pH
comes out to be 7. It is not possible. This indicates that solution is very
dilute. Hence,
no
Total hydrogen
ion concentration
=
[H +]
=
⎡Contribution of
⎢H O + ion
3
⎢concentration
⎢of acid
⎣
=
10–7 + 10–7.
⎡Contribution of
⎤
⎢H 3 O + ion
⎥
+
⎢concentration
⎥
⎢of water
⎥
⎣
⎦
pH = 2 × 10 –7 = 7 – log 2 = 7 – 0.3010 = 6.6990
Exemplar Problems, Chemistry
98
⎤
⎥
⎥
⎥
⎦
31.
BaSO4 (s)
2–
U Ba2+ (aq) + SO4 (aq)
At t = 0
1
0
0
At equilibrium in water
1–S
S
S
At equilibrium in the presence
of sulphuric acid
1–S
S
(S+0.01)
K sp for BaSO4 in water = [Ba2+] [ SO24 – ] = (S) (S) = S2
But S = 8 × 10–4 mol dm–3
–4 2
–8
∴ K sp = (8×10 ) = 64 × 10
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... (1)
The expression for K sp in the presence of sulphuric acid will be as follows :
K sp = (S) (S + 0.01)
... (2)
Since value of Ksp will not change in the presence of sulphuric acid,
therefore from (1) and (2)
(S) (S + 0.01) = 64 × 10–8
⇒
S2 + 0.01 S = 64 × 10–8
⇒
S + 0.01 S – 64 × 10 = 0
2
–8
– 0.01 ± (0.01) + (4 × 64 × 10 )
2
2
⇒
S=
=
– 0.01 ± 10
–4
–8
+ (256 × 10 )
–8
2
–4
=
– 0.01 ± 10
=
2
–2
no
=
=
=
–2
– 0.01 ± 10 (1 + 256 × 10 )
2
– 0.01 ± 10
2
– 10
–2
–2
1 + 0.256
1.256
+ (1.12 × 10 )
2
(–1+1.12) × 10
2
–2
–2
=
0.12
–2
× 10
2
= 6 × 10–4 mol dm–3
99
Equilibrium
32.
pH of HOCl = 2.85
But, – pH = log [H+ ]
+
∴ – 2.85 = log [H ]
⇒ 3 .15 = log [H ]
+
⇒
+
[H ] = 1.413 × 10–3
For weak mono basic acid [H+ ] =
Ka × C
+ 2
[H ]
(1.413 × 10 )
=
C
0.08
–3 2
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⇒
Ka =
= 24.957 × 10 –6 = 2.4957 × 10–5
33.
pH of Solution A = 6
Therefore, concentration of [H+] ion in solution A = 10–6 mol L–1
pH of Solution B = 4
+
–4
–1
Therefore, Concentration of [H ] ion concentration of solution B = 10 mol L
On mixing one litre of each solution, total volume = 1L + 1L = 2L
+
Amount of H ions in 1L of Solution A= Concentration × volume V
= 10 –6 mol × 1L
Amount of H+ ions in 1L of solution B = 10–4 mol × 1L
+
∴ Total amount of H ions in the solution formed by mixing solutions A
and B is (10 –6 mol + 10–4 mol)
This amount is present in 2L solution.
−4
∴ Total [H+ ] =
10 (1 + 0.01) 1.01 × 10
1.01 × 10
–1
=
mol L =
2
2
2
–4
–4
–1
mol L
= 0.5 × 10–4 mol L–1
= 5 × 10 –5 mol L–1
+
no
pH = – log [H ] = – log (5 × 10–5)
= – [log 5 + (– 5 log 10)]
= – log 5 + 5
= 5 – log 5
= 5 – 0.6990
= 4.3010 = 4.3
Exemplar Problems, Chemistry 100
34.
Let S be the solubility of Al(OH) 3.
Al (OH)3
U
Al3+ (aq) + 3OH– (aq)
Concentration of
species at t = 0
1
0
0
Concentration of various
species at equilibrium
1–S
S
3S
3+
– 3
3
4
K sp = [Al ] [OH ] = (S) (3S) = 27 S
K sp
4
S =
–12
= 1 × 10
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27
27 × 10
27 × 10
–11
=
S = 1× 10–3 mol L–1
(i)
Solubility of Al(OH)3
Molar mass of Al (OH)3 is 78 g. Therefore,
Solubility of Al (OH)3 in g L–1 = 1 × 10–3 × 78 g L–1 = 78 × 10–3 g L–1
–2
–1
= 7.8 × 10 g L
(ii)
pH of the solution
S = 1×10–3 mol L–1
–
–3
–3
[OH ] = 3S = 3×1×10 = 3 × 10
pOH = 3 – log 3
pH = 14 – pOH= 11 + log 3 = 11.4771
35.
K sp of PbCl2 = 3.2 × 10–8
Let S be the solubility of PbCl 2.
PbCl2 (s)
U
Pb2+ (aq) + 2Cl– (aq)
Concentration of
species at t = 0
1
0
0
Concentration of various
species at equilibrium
1–S
S
2S
no
K sp = [Pb2+] [Cl – ]2 = (S) (2S) 2 = 4S 3
K sp = 4S3
K sp
3
S =
S=
4
3
=
3.2 × 10
4
8 × 10
–9
–8
= 2 × 10
–1
–9
–1
mol L = 8 × 10 mol L
–3
mol L –1 ∴ S = 2 × 10 –3 mol L –1
101 Equilibrium
Molar mass of PbCl2 = 278
–3
–1
∴ Solubility of PbCl2 in g L–1 = 2 × 10 × 278 g L
= 556 × 10
–3
–1
gL
= 0.556 g L–1
To get saturated solution, 0.556 g of PbCl2 is dissolved in 1 L water.
0.1 g PbCl2 is dissolved in
0.1
L = 0.1798 L water.
0.556
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To make a saturated solution, dissolution of 0.1 g PbCl2 in 0.1798 L ≈ 0.2 L of
water will be required.
V
V
V
V
Δr H = Δ f H [CaO(s)] + Δf H [CO2(g)] – Δf H [CaCO3(s)]
37.
V
–1
∴ Δr H = 178.3 kJ mol
The reaction is endothermic. Hence, according to Le-Chatelier’s principle,
reaction will proceed in forward direction on increasing temperature.
IV. Matching Type
38.
(i) → (b)
(ii) → (d)
(iii) → (c)
39.
(i) → (d)
(ii) → (c)
(iii) → (b)
40.
(i) → (d)
(ii) → (a)
(iii) → (b)
41.
(i) → (b)
(ii) → (e)
(iii) → (c)
42.
(i) → (c)
(ii) → (a)
(iii) → (b)
43.
(i) → (b) and (c) (ii) → (d)
(iii) → (a)
(iv) → (a)
(iv) → (d)
V. Assertion and Reason Type
44. (i)
45. (i)
46. (ii)
47.(iii)
48. (i)
49. (iii)
50. (iv)
no
VI. Long Answer Type
51.
(i)
Qc < Kc
(ii)
Qc > Kc
(iii)
Qc = Kc
where, Qc is reaction quotient in terms of concentration and K c is
equilibrium constant.
Exemplar Problems, Chemistry 102
53.
p+
q−
[Hint : A x B y
p+
q–
U x A (aq) + y B (aq)
S moles of A xBy dissolve to give x S moles of A
54.
p+
q–
and y S moles of B .]
ΔG = ΔGV + RT lnQ
ΔGV = Change in free energy as the reaction proceeds
ΔG = Standard free energy change
Q = Reaction quotient
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R = Gas constant
T = Absolute temperature
Since ΔGV = – RT lnK
Q
∴ ΔG = – RT lnK + RT lnQ = RT ln K
If Q < K, ΔG will be negative. Reaction proceeds in the forward direction.
If Q = K, ΔG = 0, no net reaction.
no
[Hint: Next relate Q with concentration of CO, H2, CH4 and H2O in view of
reduced volume (increased pressure). Show that Q < K and hence the
reaction proceeds in forward direction.]
103 Equilibrium
Unit
8
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REDOX REAC
TIONS
REACTIONS
I. Multiple Choice Questions (Type-I)
1.
2.
Which of the following is not an example of redox reaction?
(i)
CuO + H2 ⎯→ Cu + H2O
(ii)
Fe2O3 + 3CO ⎯→ 2Fe + 3CO 2
(iii)
2K + F2 ⎯→ 2KF
(iv)
BaCl2 + H2SO4 ⎯→ BaSO4 + 2HCl
V
The more positive the value of E , the greater is the tendency of the species to
get reduced. Using the standard electrode potential of redox couples given
below find out which of the following is the strongest oxidising agent.
V
E values: Fe3+ /Fe2+ = + 0.77; I2(s)/I– = + 0.54;
Cu 2+/Cu = + 0.34; Ag+ /Ag = + 0.80V
Fe3+
(ii)
I2(s)
(iii)
Cu2+
(iv)
Ag+
V
E values of some redox couples are given below. On the basis of these values
choose the correct option.
V
no
3.
(i)
E values : Br 2/Br– = + 1.90; Ag + /Ag(s) = + 0.80
Cu 2+/Cu(s) = + 0.34; I2(s)/I– = + 0.54
(i)
Cu will reduce Br–
(ii)
Cu will reduce Ag
(iii)
Cu will reduce I–
(iv)
Cu will reduce Br2
4.
Using the standard electrode potential, find out the pair between which redox
reaction is not feasible.
V
3+
2+
–
E values : Fe /Fe = + 0.77; I2/I = + 0.54;
+
Cu2+/Cu = + 0.34; Ag /Ag = + 0.80 V
Fe 3+ and I
(ii)
Ag+ and Cu
(iii)
Fe
(iv)
Ag and Fe3+
3+
and Cu
Thiosulphate reacts differently with iodine and bromine in the reactions given
below:
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5.
–
(i)
+ 2I–
2S2O 32– + I2 → S4O2–
6
S2O3 + 2Br2 + 5H2O → 2SO4 + 2Br + 10 H
2–
–
2–
+
Which of the following statements justifies the above dual behaviour of
thiosulphate?
6.
Bromine is a stronger oxidant than iodine.
(ii)
Bromine is a weaker oxidant than iodine.
(iii)
Thiosulphate undergoes oxidation by bromine and reduction by iodine
in these reactions.
(iv)
Bromine undergoes oxidation and iodine undergoes reduction in these
reactions.
The oxidation number of an element in a compound is evaluated on the basis
of certain rules. Which of the following rules is not correct in this respect?
(i)
The oxidation number of hydrogen is always +1.
(ii)
The algebraic sum of all the oxidation numbers in a compound is zero.
(iii)
An element in the free or the uncombined state bears oxidation
number zero.
(iv)
In all its compounds, the oxidation number of fluorine is – 1.
In which of the following compounds, an element exhibits two different
oxidation states.
(i)
NH2OH
(ii)
NH4NO3
no
7.
(i)
8.
(iii)
N2H4
(iv)
N3H
Which of the following arrangements represent increasing oxidation number
of the central atom?
2–
–
(i)
CrO–2 , ClO3–
(ii)
ClO 3– , CrO 42– , MnO–4 , CrO 2–
, CrO4 , MnO4
105 Redox Reactions
(iii)
CrO2– , ClO3– , MnO4– , CrO42–
(iv)
CrO42–, MnO4– , CrO2– , ClO3–
9. The largest oxidation number exhibited by an element depends on its outer
electronic configuration. With which of the following outer electronic
configurations the element will exhibit largest oxidation number?
(i)
3d14s 2
(ii)
3d 4s
(iii)
3d54s 1
(iv)
3d54s 2
2
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3
10. Identify disproportionation reaction
(i)
CH4 + 2O2 ⎯→ CO2 + 2H2O
(ii)
CH4 + 4Cl2 ⎯→ CCl4 + 4HCl
(iii)
2F2 + 2OH– ⎯→ 2F– + OF2 + H2O
(iv)
2NO2 + 2OH ⎯→ NO2 + NO3 + H2O
–
–
–
11. Which of the following elements does not show disproportionation tendency?
(i)
Cl
(ii)
Br
(iii)
F
(iv)
I
II. Multiple Choice Questions (Type-II)
In the following questions two or more options may be correct.
12. Which of the following statement(s) is/are not true about the following
decomposition reaction.
2KClO3 → 2KCl + 3O2
Potassium is undergoing oxidation
(ii)
Chlorine is undergoing oxidation
(iii)
Oxygen is reduced
(iv)
None of the species are undergoing oxidation or reduction
no
(i)
13. Identify the correct statement (s) in relation to the following reaction:
Zn + 2HCl → ZnCl2 + H 2
(i)
Zinc is acting as an oxidant
(ii)
Chlorine is acting as a reductant
(iii)
Hydrogen ion is acting as an oxidant
(iv)
Zinc is acting as a reductant
Exemplar Problems, Chemistry 106
14. The exhibition of various oxidation states by an element is also related to the
outer orbital electronic configuration of its atom. Atom(s) having which of the
following outermost electronic configurations will exhibit more than one oxidation
state in its compounds.
1
(i)
3s
(ii)
3d14s 2
(iii)
3d24s 2
(iv)
3s 3p
2
3
15. Identify the correct statements with reference to the given reaction
–
–
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P 4 + 3OH + 3H2O → PH3 + 3H2PO2
(i)
Phosphorus is undergoing reduction only.
(ii)
Phosphorus is undergoing oxidation only.
(iii)
Phosphorus is undergoing oxidation as well as reduction.
(iv)
Hydrogen is undergoing neither oxidation nor reduction.
16. Which of the following electrodes will act as anodes, when connected to
Standard Hydrogen Electrode?
V
(i)
Al/Al3+
(ii)
Fe/Fe
(iii)
Cu/Cu2+
E = + 0.34
(iv)
F2 (g)/2F– (aq)
E = + 2.87
E = –1.66
V
2+
E = – 0.44
V
V
III. Short Answer Type
17. The reaction
Cl2 (g) + 2OH (aq) ⎯→ ClO (aq) + Cl (aq) + H2O (l )
–
–
–
represents the process of bleaching. Identify and name the species that
bleaches the substances due to its oxidising action.
18.
–
MnO 2–
4 undergoes disproportionation reaction in acidic medium but MnO4
does not. Give reason.
no
19. PbO and PbO2 react with HCl according to following chemical equations :
2PbO + 4HCl ⎯→ 2PbCl2 + 2H2O
PbO2 + 4HCl ⎯→ PbCl2 + Cl2 + 2H2O
Why do these compounds differ in their reactivity?
20. Nitric acid is an oxidising agent and reacts with PbO but it does not react
with PbO2. Explain why?
107 Redox Reactions
21. Write balanced chemical equation for the following reactions:
(i) Permanganate ion (MnO4– ) reacts with sulphur dioxide gas in acidic
medium to produce Mn 2+ and hydrogensulphate ion.
(Balance by ion electron method)
–
(ii) Reaction of liquid hydrazine (N2H4) with chlorate ion (ClO3 ) in basic
medium produces nitric oxide gas and chloride ion in gaseous state.
(Balance by oxidation number method)
(iii) Dichlorine heptaoxide (Cl2O7) in gaseous state combines with an aqueous
solution of hydrogen peroxide in acidic medium to give chlorite ion
–
(ClO2 ) and oxygen gas.
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(Balance by ion electron method)
22. Calculate the oxidation number of phosphorus in the following species.
2–
3–
(a) HPO3 and
(b) PO 4
23. Calculate the oxidation number of each sulphur atom in the following
compounds:
(a) Na2S2O3
(b) Na2S4O 6
(c) Na2SO 3
(d) Na2SO 4
24. Balance the following equations by the oxidation number method.
(i)
Fe2+ + H+ + Cr2 O 7 ⎯→ Cr
(ii)
I 2 + N O3– ⎯→ NO2 + I O3–
(iii)
I 2 + S2 O3 ⎯→ I + S4 O6
(iv)
MnO2 + C2 O4 ⎯→ Mn
3+
2–
–
2–
3+
+ Fe + H2O
2–
2+
2–
+ CO2
25. Identify the redox reactions out of the following reactions and identify the
oxidising and reducing agents in them.
(i)
3HCl(aq) + HNO3 (aq) ⎯→ Cl2 (g) + NOCl (g) + 2H2O (l )
(ii)
HgCl2 (aq) + 2KI (aq) ⎯→ HgI2 (s) + 2KCl (aq)
(iii)
Δ
Fe2O 3 (s) + 3CO (g) ⎯⎯
⎯
→ 2Fe (s) + 3CO2 (g)
(iv)
PCl3 (l) + 3H 2O (l) ⎯→ 3HCl (aq) + H3 PO3 (aq)
(v)
4NH3 + 3O2 (g) ⎯→ 2N2 (g) + 6H2O (g)
no
26. Balance the following ionic equations
(i)
+ H+ + I – ⎯→ Cr3+ + I2 + H2O
Cr 2 O2–
7
(ii)
Cr 2 O7 + Fe
(iii)
+ H+ ⎯→ Mn2+ + S O2–
+ H2O
Mn O4– + S O2–
3
4
(iv)
Mn O4 + H + Br ⎯→ Mn
2+
2–
–
+
+ H ⎯→ Cr
+
–
Exemplar Problems, Chemistry 108
3+
2+
3+
+ Fe + H2O
+ Br2 + H2O
IV. Matching Type
27. Match Column I with Column II for the oxidation states of the central atoms.
Column I
(i)
Cr 2O
(ii)
(iii)
(iv)
2–
7
–
4
Column II
(a)
+3
MnO
VO3–
(b)
(c)
+4
+5
FeF63–
(d)
+6
(e)
+7
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28. Match the items in Column I with relevant items in Column II.
Column I
Column II
(i)
Ions having positive charge
(a)
+7
(ii)
The sum of oxidation number
(b)
–1
(iii)
of all atoms in a neutral molecule
Oxidation number of hydrogen ion (H +)
(c)
(d)
+1
0
(iv)
(v)
Oxidation number of fluorine in NaF
Ions having negative charge
(e)
(f)
Cation
Anion
V. Assertion and Reason Type
In the following questions a statement of assertion (A) followed by a statement
of reason (R) is given. Choose the correct option out of the choices given
below each question.
29. Assertion (A) : Among halogens fluorine is the best oxidant.
Reason (R) :
Fluorine is the most electronegative atom.
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
Both A and R are false.
30. Assertion (A): In the reaction between potassium permanganate and
potassium iodide, permanganate ions act as oxidising agent.
no
Reason (R) :
Oxidation state of manganese changes from +2 to +7 during
the reaction.
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
Both A and R are false.
109 Redox Reactions
31. Assertion (A) : The decomposition of hydrogen peroxide to form water and
oxygen is an example of disproportionation reaction.
Reason (R) :
The oxygen of peroxide is in –1 oxidation state and it is
converted to zero oxidation state in O2 and –2 oxidation state
in H2O.
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
Both A and R are false.
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(i)
32. Assertion (A) : Redox couple is the combination of oxidised and reduced
form of a substance involved in an oxidation or reduction
half cell.
V
V
In the representation E Fe3+ / Fe2 + and ECu2+ /Cu , Fe 3+/ Fe2+
Reason (R) :
and Cu 2+ / Cu are redox couples.
(i)
Both A and R are true and R is the correct explanation of A.
(ii)
Both A and R are true but R is not the correct explanation of A.
(iii)
A is true but R is false.
(iv)
Both A and R are false.
VI. Long Answer Type
33. Explain redox reactions on the basis of electron transfer. Give suitable examples.
34. On the basis of standard electrode potential values, suggest which of the
V
following reactions would take place? (Consult the book for E value).
(i)
Cu + Zn2+ ⎯→ Cu2+ + Zn
(ii)
Mg + Fe
(iii)
Br2 + 2Cl ⎯→ Cl2 + 2Br–
(iv)
Fe + Cd ⎯→ Cd + Fe
2+
⎯→ Mg
2+
+ Fe
–
2+
2+
35. Why does fluorine not show disporportionation reaction?
no
36. Write redox couples involved in the reactions (i) to (iv) given in question 34.
37. Find out the oxidation number of chlorine in the following compounds and
arrange them in increasing order of oxidation number of chlorine.
NaClO4, NaClO3, NaClO, KClO2, Cl2O7, ClO3, Cl2O, NaCl, Cl2, ClO2.
Which oxidation state is not present in any of the above compounds?
38. Which method can be used to find out strength of reductant/oxidant in a
solution? Explain with an example.
Exemplar Problems, Chemistry 110
ANSWERS
I. Multiple Choice Questions (Type-I)
1. (iv)
7. (ii)
2. (iv)
8. (i)
3. (iv)
9. (iv)
4. (iv)
10. (iv)
5. (i)
11. (iii)
6. (i)
II. Multiple Choice Questions (Type-II)
13. (iii), (iv)
16. (i), (ii)
14. (iii), (iv)
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12. (i), (iv)
15. (iii), (iv)
III. Short Answer Type
17.
Hypochlorite ion
18.
In MnO–4 , Mn is in the highest oxidation state i.e. +7. Therefore, it does
2–
not undergo disproportionation. MnO4 undergoes disproportionation
as follows :
+ 4H+ ⎯→ 2MnO 4– + MnO2 + 2H2O
3MnO2–
4
19.
2PbO + 4HCl ⎯→ 2PbCl 2 + 2H2O (Acid base reaction)
PbO2 + 4HCl ⎯→ PbCl2 + Cl2 + 2H2O (Redox reaction)
(Hint : Note the oxidation number of lead in the oxides)
20.
PbO is a basic oxide and simple acid base reaction takes place between
PbO and HNO3. On the other hand in PbO2 lead is in + 4 oxidation state
and cannot be oxidised further. Therefore no reaction takes place. Thus,
PbO2 is passive, only PbO reacts with HNO3.
2PbO + 4HNO 3 ⎯→ 2Pb (NO3)2 + 2H2O (Acid base reaction)
22.
(a) +3,
(b) +5
23.
(a) +2
(b) +5, 0, 0, +5
(c) +4
(d) +6
no
Justification :
Write Lewis structure of each ion then assign electron pair shared between
atoms of different electronegativity to more electronegative atom and distribute
the electron pair shared between atoms of same element equally. Now count
the number of electrons possessed by each atom. Find out the difference in
number of electrons possessed by neutral atom and that possessed by atom in
the compound. This difference is the oxidation number. If atom present in the
compound possesses more electrons than the neutral atom, the oxidation
111 Redox Reactions
number is negative. If it possesses less electrons then oxidation number is
positive.
2–
(i) Lewis structure of S2O4 can be written as follows :
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Electron pair shared between sulphur and oxygen is assigned to oxygen
atoms because of more electronegativity of oxygen. Thus each sulphur atom
is deficient of two electrons with respect to neutral sulphur atom hence,
each sulphur atom is in +2 oxidation state. Each oxygen atom gets two
excess electrons hence, it is in –2 oxidation state. Lewis structure of S 4O 62–
can be written as follows :
To find out oxidation state of each atom we distribute electrons of electron
pair shared between two sulphur atoms equally (i.e. one electron is assigned
to each sulphur atom). Both the electrons of electron pair shared between
sulphur and oxygen atom are assigned to oxygen as oxygen is more
electronegative. Thus we find that each of the central sulphur atoms obtain
six electrons. This number is same as that in the outer shell of neutral
sulphur atom hence oxidation state of central sulphur atoms is zero. Each
of the sulphur atoms attached to oxygen atoms obtain only one electron as
its share. This number is less by five electrons in comparison to the neutral
sulphur atom. So, outer sulphur atoms are in +5 oxidation state. Therefore
average oxidation state of sulphur atoms is :
5 + 0 + 0 + 5 10
=
= 2 .5
4
4
By using the formula we obtain average oxidation state of the particular
type of atoms. Real oxidation state can be obtained only by writing the
complete structural formula. Similarly we can see that each oxygen atom
is in – 2 oxidation state.
2–
no
In the same way one can find out the oxidation state of each atom in SO3
and SO42– ions. Oxidation state of metal atoms will be +1 as these will lose
one electron in each case.
IV. Matching Type
27.
(i)→ (d)
(ii)→ (e)
(iii) → (c)
(iv)→(a)
28.
(i)→ (e)
(ii) → (d)
(iii) → (c)
(iv) → (b)
31. (i)
32. (ii)
V. Assertion and Reason Type
29. (ii)
30. (iii)
Exemplar Problems, Chemistry 112
(v) → (f)
Unit
9
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HYDR
OGEN
YDROGEN
I. Multiple Choice Questions (Type-I)
1.
2.
(i)
Its tendency to lose an electron to form a cation.
(ii)
Its tendency to gain a single electron in its valence shell to attain stable
electronic configuration.
(iii)
Its low negative electron gain enthalpy value.
(iv)
Its small size.
+
Why does H ion always get associated with other atoms or molecules?
(i)
Ionisation enthalpy of hydrogen resembles that of alkali metals.
(ii)
Its reactivity is similar to halogens.
(iii)
It resembles both alkali metals and halogens.
(iv)
Loss of an electron from hydrogen atom results in a nucleus of very
small size as compared to other atoms or ions. Due to smal size it cannot
exist free.
Metal hydrides are ionic, covalent or molecular in nature. Among LiH, NaH,
KH, RbH, CsH, the correct order of increasing ionic character is
(i)
LiH > NaH > CsH > KH>RbH
(ii)
LiH < NaH < KH < RbH < CsH
(iii)
RbH > CsH > NaH > KH > LiH
(iv)
NaH > CsH > RbH > LiH > KH
no
3.
Hydrogen resembles halogens in many respects for which several factors are
responsible. Of the following factors which one is most important in this respect?
4.
Which of the following hydrides is electron-precise hydride?
(i)
B2H6
(ii)
NH3
H2O
(iv)
CH4
Radioactive elements emit α, β and γ rays and are characterised by their halflives. The radioactive isotope of hydrogen is
(i)
Protium
(ii)
Deuterium
(iii)
Tritium
(iv)
Hydronium
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5.
(iii)
6.
Consider the reactions
(A) H2O2 + 2HI ⎯→ I2 + 2H2O
(B) HOCl + H2O2 ⎯→ H3O + Cl + O2
+
–
Which of the following statements is correct about H2O2 with reference to
these reactions? Hydrogen perioxide is ________.
7.
an oxidising agent in both (A) and (B)
(ii)
an oxidising agent in (A) and reducing agent in (B)
(iii)
a reducing agent in (A) and oxidising agent in (B)
(iv)
a reducing agent in both (A) and (B)
The oxide that gives H2O2 on treatment with dilute H2SO4 is —
(i)
PbO2
(ii)
BaO2 .8H2O + O2
(iii)
MnO2
(iv)
TiO2
Which of the following equations depict the oxidising nature of H2O2?
(i)
2MnO4– + 6H+ + 5H2 O2 ⎯→ 2Mn2 + + 8H2 O + 5O2
(ii)
2Fe3+ + 2H+ + H2 O2 ⎯→ 2Fe2 + + 2H2 O + O2
(iii)
2I – + 2H+ + H2 O2 ⎯→ I2 + 2H2 O
(iv)
KIO4 + H2O2 ⎯→ KIO3 + H2O + O2
no
8.
(i)
9.
Which of the following equation depicts reducing nature of H2O2?
(i)
2[Fe(CN)6] + 2H + H2O2 ⎯→ 2[Fe (CN)6] + 2H2O
(ii)
I2 + H2O2 + 2OH ⎯→ 2I + 2H2O + O2
(iii)
Mn + H2O2 ⎯→ Mn4+ + 2OH
(iv)
PbS + 4H2O2 ⎯→ PbSO4 + 4H2O
4–
+
–
2+
Exemplar Problems, Chemistry 114
3–
–
–
10. Hydrogen peroxide is _________.
(i)
an oxidising agent
(ii)
a reducing agent
(iii)
both an oxidising and a reducing agent
(iv)
neither oxidising nor reducing agent
11. Which of the following reactions increases production of dihydrogen from
synthesis gas?
1270 K
CH4 (g) + H2O (g) ⎯⎯⎯⎯
CO (g) + 3H2 (g)
Ni →
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(i)
(ii)
1270 K
C (s) + H2O (g) ⎯⎯⎯⎯
→ CO (g) + H2 (g)
(iii)
CO (g) + H2O (g) ⎯⎯⎯⎯→
CO2 (g) + H2 (g)
Catalyst
(iv)
2CO + 5H2
C2H6 + 2H2O ⎯⎯⎯⎯
Ni →
673 K
1270 K
12. When sodium peroxide is treated with dilute sulphuric acid, we get ______.
(i)
sodium sulphate and water
(ii)
sodium sulphate and oxygen
(iii)
sodium sulphate, hydrogen and oxygen
(iv)
sodium sulphate and hydrogen peroxide
13. Hydrogen peroxide is obtained by the electrolysis of ______.
(i)
water
(ii)
sulphuric acid
(iii)
hydrochloric acid
(iv)
fused sodium peroxide
14. Which of the following reactions is an example of use of water gas in the
synthesis of other compounds?
1270 K
(i)
CH4 (g) + H2O (g) ⎯⎯⎯⎯
CO (g) + H2 (g)
Ni →
(ii)
CO (g) + H2O (g) ⎯⎯⎯⎯→
CO2 (g) + H2 (g)
Catalyst
(iii)
nCO + (2n+1) H2
CnH2n+2 + nH2O (g) ⎯⎯⎯⎯
Ni →
(iv)
CO (g) + 2H2 (g) ⎯⎯⎯⎯→
CH3OH (l )
Catalyst
no
673 K
1270 K
Cobalt
15. Which of the following ions will cause hardness in water sample?
(i)
Ca2+
(ii)
Na+
115 Hydrogen
–
(iii)
Cl
(iv)
K
+
16. Which of the following compounds is used for water softening?
(i)
Ca3 (PO4)2
(ii)
Na3PO4
(iii)
Na6P6O18
(iv)
Na2HPO4
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17. Elements of which of the following group(s) of periodic table do not form
hydrides.
(i)
Groups 7, 8, 9
(ii)
Group 13
(iii)
Groups 15, 16, 17
(iv)
Group 14
18. Only one element of ________ forms hydride.
(i)
group 6
(ii)
group 7
(iii)
group 8
(iv)
group 9
II. Multiple Choice Questions (Type-II)
In the following questions two or more options may be correct.
19. Which of the following statements are not true for hydrogen?
(i)
(ii)
(iii)
(iv)
It exists as diatomic molecule.
It has one electron in the outermost shell.
It can lose an electron to form a cation which can freely exist
It forms a large number of ionic compounds by losing an electron.
no
20. Dihydrogen can be prepared on commercial scale by different methods. In
its preparation by the action of steam on hydrocarbons, a mixture of CO and
H2 gas is formed. It is known as ____________.
(i) Water gas
(ii) Syngas
(iii) Producer gas
(d) Industrial gas
21. Which of the following statement(s) is/are correct in the case of heavy water?
(i) Heavy water is used as a moderator in nuclear reactor.
(ii) Heavy water is more effective as solvent than ordinary water.
Exemplar Problems, Chemistry 116
(iii)
(iv)
Heavy water is more associated than ordinary water.
Heavy water has lower boiling point than ordinary water.
22. Which of the following statements about hydrogen are correct?
(i) Hydrogen has three isotopes of which protium is the most common.
(ii) Hydrogen never acts as cation in ionic salts.
+
(iii) Hydrogen ion, H , exists freely in solution.
(iv) Dihydrogen does not act as a reducing agent.
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23. Some of the properties of water are described below. Which of them is/are
not correct?
(i) Water is known to be a universal solvent.
(ii) Hydrogen bonding is present to a large extent in liquid water.
(iii) There is no hydrogen bonding in the frozen state of water.
(iv) Frozen water is heavier than liquid water.
24. Hardness of water may be temporary or permanent. Permanent hardness is
due to the presence of
(i) Chlorides of Ca and Mg in water
(ii) Sulphates of Ca and Mg in water
(iii) Hydrogen carbonates of Ca and Mg in water
(iv) Carbonates of alkali metals in water
25. Which of the following statements is correct?
(i) Elements of group 15 form electron deficient hydrides.
(ii) All elements of group 14 form electron precise hydrides.
(iii) Electron precise hydrides have tetrahedral geometries.
(iv) Electron rich hydrides can act as Lewis acids.
no
26. Which of the following statements is correct?
(i) Hydrides of group 13 act as Lewis acids.
(ii) Hydrides of group 14 are electron deficient hydrides.
(iii) Hydrides of group 14 act as Lewis acids.
(iv) Hydrides of group 15 act as Lewis bases.
27. Which of the following statements is correct?
(i) Metallic hydrides are deficient of hydrogen.
(ii) Metallic hydrides conduct heat and electricity.
(iii) Ionic hydrides do not conduct electricity in solid state.
(iv) Ionic hydrides are very good conductors of electricity in solid state.
117 Hydrogen
III. Short Answer Type
28. How can production of hydrogen from water gas be increased by using water
gas shift reaction?
29. What are metallic/interstitial hydrides? How do they differ from molecular
hydrides?
30. Name the classes of hydrides to which H2O, B2H6 and NaH belong.
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31. If same mass of liquid water and a piece of ice is taken, then why is the density
of ice less than that of liquid water?
32. Complete the following equations:
(i)
PbS (s) + H2O2(aq) ⎯→
(ii)
CO (g) + 2H2 (g) ⎯⎯⎯⎯→
Catalyst
Cobalt
33. Give reasons:
(i)
Lakes freeze from top towards bottom.
(ii)
Ice floats on water.
34. What do you understand by the term ‘auto protolysis of water’ ? What is its
significance?
35. Discuss briefly de-mineralisation of water by ion exchange resin.
36. Molecular hydrides are classified as electron deficient, electron precise and
electron rich compounds. Explain each type with two examples.
37. How is heavy water prepared? Compare its physical properties with those of
ordinary water.
38. Write one chemical reaction for the preparation of D2O2.
39. Calculate the strength of 5 volume H2O2 solution.
40.
(i) Draw the gas phase and solid phase structure of H2O2.
(ii) H2O2 is a better oxidising agent than water. Explain.
no
41. Melting point, enthalpy of vapourisation and viscosity data of H2O and D2O is
given below :
H2O
D2O
Melting point / K
373.0
374.4
Enthalpy of vapourisation
–1
at (373 K)/ kJ mol
40.66
41.61
Viscosity/centipoise
0.8903
1.107
On the basis of this data explain in which of these liquids intermolecular
forces are stronger?
Exemplar Problems, Chemistry 118
42. Dihydrogen reacts with dioxygen (O2) to form water. Write the name and
formula of the product when the isotope of hydrogen which has one proton
and one neutron in its nucleus is treated with oxygen. Will the reactivity of
both the isotopes be the same towards oxygen? Justify your answer.
43. Explain why HCl is a gas and HF is a liquid.
44. When the first element of the periodic table is treated with dioxygen, it gives a
compound whose solid state floats on its liquid state. This compound has an
ability to act as an acid as well as a base. What products will be formed when
this compound undergoes autoionisation?
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45. Rohan heard that instructions were given to the laboratory attendent to store
a particular chemical i.e., keep it in the dark room, add some urea in it, and
keep it away from dust. This chemical acts as an oxidising as well as a
reducing agent in both acidic and alkaline media. This chemical is important
for use in the pollution control treatment of domestic and industrial effluents.
(i) Write the name of this compound.
(ii) Explain why such precautions are taken for storing this chemical.
46. Give reasons why hydrogen resembles alkali metals?
47. Hydrogen generally forms covalent compounds. Give reason.
48. Why is the Ionisation enthalpy of hydrogen higher than that of sodium?
49. Basic principle of hydrogen economy is transportation and storage of energy
in the form of liquid or gaseous hydrogen. Which property of hydrogen may
be useful for this purpose? Support your answer with the chemical equation
if required.
50. What is the importance of heavy water?
51. Write the Lewis structure of hydrogen peroxide.
52. An acidic solution of hydrogen peroxide behaves as an oxidising as well as
reducing agent. Illustrate it with the help of a chemical equation.
53. With the help of suitable examples, explain the property of H2O2 that is
responsible for its bleaching action?
no
54. Why is water molecule polar?
55. Why does water show high boiling point as compared to hydrogen sulphide?
Give reasons for your answer.
56. Why can dilute solutions of hydrogen peroxide not be concentrated by
heating. How can a concentrated solution of hydrogen peroxide be obtained?
57. Why is hydrogen peroxide stored in wax lined bottles?
119 Hydrogen
58. Why does hard water not form lather with soap?
59. Phosphoric acid is preferred over sulphuric acid in preparing hydrogen
peroxide from peroxides. Why?
60. How will you account for 104.5° bond angle in water?
61. Write redox reaction between fluorine and water.
62. Write two reactions to explain amphoteric nature of water.
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IV. Matching Type
63. Correlate the items listed in Column I with those listed in Column II. Find
out as many correlations as you can.
Column I
Column II
(i)
Synthesis gas
(a) Na2 [Na4(PO3)6]
(ii)
Dihydrogen
(b) Oxidising agent
(iii)
Heavy water
(c) Softening of water
(iv)
Calgon
(d) Reducing agent
(v)
Hydrogen peroxide
(e) Stoichiometric compounds of
s-block elements
(vi)
Salt like hydrides
(f)
Prolonged electrolysis of water
(g) Zn + NaOH
(h) Zn + dil. H2SO4
(i)
Synthesis of methanol
(j)
Mixture of CO and H2
64. Match Column I with Column II for the given properties/applications
mentioned therein.
no
Column I
Column II
(i)
H
(a)
Used in the name of perhydrol.
(ii)
H2
(b)
Can be reduced to dihydrogen by
NaH.
(iii)
H2O
(c)
Can be used in hydroformylation of
olefin.
(iv)
H2O 2
(d)
Can be used in cutting and welding.
Exemplar Problems, Chemistry 120
65. Match the terms in Column I with the relevant item in Column II.
Column I
Column II
Electrolysis of water produces
(a) atomic reactor
(ii)
Lithium aluminium hydride is used as
(b) polar molecule
(iii)
Hydrogen chloride is a
(c) recombines on metal
surface to generate high
temperature
(iv)
Heavy water is used in
(d) reducing agent
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(i)
(v)
Atomic hydrogen
(e) hydrogen and oxygen
66. Match the items in Column I with the relevant item in Column II.
Column I
Column II
(i)
Hydrogen peroxide is used as a
(a)
zeolite
(ii)
Used in Calgon method
(b)
perhydrol
(iii)
Permanent hardness of hard
water is removed by
(c)
sodium
hexametaphosphate
(d)
propellant
V. Assertion and Reason Type
In the following questions a statement of Assertion (A) followed by a statement
of Reason (R) is given. Choose the correct option out of the options given
below each question.
67. Assertion (A) : Permanent hardness of water is removed by treatment with
washing soda.
Reason (R) :
Washing soda reacts with soluble magnesium and calcium
sulphate to form insoluble carbonates.
Statements A and R both are correct and R is the correct explanation of A.
(ii)
A is correct but R is not correct.
no
(i)
(iii)
A and R both are correct but R is not the correct explanation of A.
(iv)
A and R both are false.
68. Assertion (A) : Some metals like platinum and palladium, can be used as
storage media for hydrogen.
Reason (R) :
Platinum and palladium can absorb large volumes of
hydrogen.
121 Hydrogen
(i)
Statements A and R both are correct and R is the correct explanation of A.
(ii)
A is correct but R is not correct.
(iii)
A and R both are correct but R is not the correct explanation of A.
(iv)
A and R both are false.
VI. Long Answer Type
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69. Atomic hydrogen combines with almost all elements but molecular hydrogen
does not. Explain.
70. How can D2O be prepared from water? Mention the physical properties in
which D2O differs from H2O. Give at least three reactions of D2O showing the
exchange of hydrogen with deuterium.
71. How will you concentrate H2O2? Show differences between structures of H2O2
and H2O by drawing their spatial structures. Also mention three important
uses of H2O2.
72.
(i)
Give a method for the manufacture of hydrogen peroxide and explain
the reactions involved therein.
(ii)
Illustrate oxidising, reducing and acidic properties of hydrogen peroxide
with equations.
73. What mass of hydrogen peroxide will be present in 2 litres of a 5 molar
solution? Calculate the mass of oxygen which will be liberated by the
decomposition of 200 mL of this solution.
74. A colourless liquid ‘A’ contains H and O elements only. It decomposes slowly
on exposure to light. It is stabilised by mixing urea to store in the presence of
light.
(i)
Suggest possible structure of A.
(ii)
Write chemical equations for its decomposition reaction in light.
75. An ionic hydride of an alkali metal has significant covalent character and is
almost unreactive towards oxygen and chlorine. This is used in the synthesis
of other useful hydrides. Write the formula of this hydride. Write its reaction
with Al2Cl6.
no
76. Sodium forms a crystalline ionic solid with dihydrogen. The solid is nonvolatile and non- conducting in nature. It reacts violently with water to
produce dihydrogen gas. Write the formula of this compound and its reaction
with water. What will happen on electrolysis of the melt of this solid.
Exemplar Problems, Chemistry 122
ANSWERS
I. Multiple Choice Questions (Type-I)
1. (ii)
2. (iv)
3. (ii)
4. (iv)
5. (iii)
6. (ii)
7. (ii)
8. (iii)
9. (ii)
10. (iii)
11. (iii)
12. (iv)
13. (ii)
14. (iv)
15. (i)
16. (iii)
17. (i)
18. (i)
II. Multiple Choice Questions (Type-II)
20. (i), (ii)
21. (i), (iii)
22. (i), (ii)
23. (iii), (iv)
24. (i), (ii)
25. (ii), (iii)
26. (i), (iv)
27. (i), (ii), (iii)
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19. (iii), (iv)
III. Short Answer Type
39.
5 volume H2O2 solution means that hydrogen peroxide contained in
1 volume of this solution will decompose to give 5 volumes of oxygen at
STP i.e. if 1L of this solution is taken, then 5 L of oxygen can be produced
from this at STP. Chemical equation for the decomposition of H2O2 is
2H2O2(l) ⎯→ O2(g) + H2O(l).
It shows that 68 g H2O2 gives 22.7 L of O2 at STP, so 5 L oxygen will be
obtained from :
68g × 5L
22.7L
=
3400
227
g H2O2 = 14.9 g ≈ 15 g H2O2
i.e., 15 g H2O2 dissolved in 1 L solution will give 5 L oxygen or 1.5 g
H2O2/100 mL solution will give 500 mL oxygen. Thus 15 g/L or 1.5%
solution is known as 5V solution of H2O2.
42.
[Hint : Heavy water; Bond dissociation energy of dihydrogen is less than
dideuterium]
44.
[Hint : H2O + H2O ⎯→ H3O + OH]
45.
(i) H2O2
+
–
no
IV. Matching Type
63.
(i) → (i), (j)
(ii) → (d), (e), (g), (h), (i)
(iii) → (f)
(iv) → (a), (c)
(v) → (b), (d)
(vi) → (e)
123 Hydrogen
64.
(i) → (d)
(ii) → (c)
(iii) → (b)
(iv) → (a)
65.
(i) → (e)
(ii) → (d)
(iii) → (b)
(iv) → (a)
(ii) → (c)
(iii) → (a), (c)
(v) → (c)
66.
(i) → (b), (d)
V. Assertion and Reason Type
68. (i)
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67. (i)
VI. Long Answer Type
68 g, 3.2 g
no
73.
Exemplar Problems, Chemistry 124
Unit
10
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THE s -BL
OCK ELEMENTS
-BLOCK
I. Multiple Choice Questions (Type-I)
1.
2.
(i)
Na
(ii)
K
(iii)
Rb
(iv)
Cs
Alkali metals react with water vigorously to form hydroxides and dihydrogen.
Which of the following alkali metals reacts with water least vigorously?
(i)
Li
(ii)
Na
(iii)
K
(iv)
Cs
The reducing power of a metal depends on various factors. Suggest the factor
which makes Li, the strongest reducing agent in aqueous solution.
(i)
Sublimation enthalpy
(ii)
Ionisation enthalpy
(iii)
Hydration enthalpy
(iv)
Electron-gain enthalpy
no
3.
The alkali metals are low melting. Which of the following alkali metal is expected
to melt if the room temperature rises to 30°C?
4.
Metal carbonates decompose on heating to give metal oxide and carbon
dioxide. Which of the metal carbonates is most stable thermally?
(i)
MgCO 3
(ii)
CaCO3
(iii)
SrCO3
(iv)
BaCO3
5. Which of the carbonates given below is unstable in air and is kept in CO2
atmosphere to avoid decomposition.
(i)
BeCO3
(ii)
MgCO3
(iii)
CaCO3
(iv)
BaCO3
6. Metals form basic hydroxides. Which of the following metal hydroxide is the
least basic?
Mg(OH)2
(ii)
Ca(OH)2
(iii)
Sr(OH)2
(iv)
Ba(OH)2
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(i)
7. Some of the Group 2 metal halides are covalent and soluble in organic solvents.
Among the following metal halides, the one which is soluble in ethanol is
(i)
BeCl2
(ii)
MgCl2
(iii)
CaCl2
(iv)
SrCl2
8. The order of decreasing ionisation enthalpy in alkali metals is
(i)
Na > Li > K > Rb
(ii)
Rb < Na < K < Li
(iii)
Li > Na > K > Rb
(iv)
K < Li < Na < Rb
9. The solubility of metal halides depends on their nature, lattice enthalpy and
hydration enthalpy of the individual ions. Amongst fluorides of alkali metals,
the lowest solubility of LiF in water is due to
(i)
Ionic nature of lithium fluoride
(ii)
High lattice enthalpy
(iii)
High hydration enthalpy for lithium ion.
(iv)
Low ionisation enthalpy of lithium atom
no
10. Amphoteric hydroxides react with both alkalies and acids. Which of the
following Group 2 metal hydroxides is soluble in sodium hydroxide?
(i)
Be(OH)2
(ii)
Mg(OH)2
(iii)
Ca(OH)2
(iv)
Ba(OH)2
Exemplar Problems, Chemistry 126
11. In the synthesis of sodium carbonate, the recovery of ammonia is done by
treating NH4Cl with Ca(OH) 2. The by-product obtained in this process is
(i)
CaCl2
(ii)
NaCl
(iii)
NaOH
(iv)
NaHCO3
12. When sodium is dissolved in liquid ammonia, a solution of deep blue colour
is obtained. The colour of the solution is due to
ammoniated electron
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(i)
(ii)
sodium ion
(iii)
sodium amide
(iv)
ammoniated sodium ion
13. By adding gypsum to cement
(i)
setting time of cement becomes less.
(ii)
setting time of cement increases.
(iii)
colour of cement becomes light.
(iv)
shining surface is obtained.
14. Dead burnt plaster is
(i)
CaSO4
(ii)
CaSO4.
(iii)
CaSO4.H2O
(iv)
CaSO4.2H2O
1
HO
2 2
15. Suspension of slaked lime in water is known as
lime water
(ii)
quick lime
(iii)
milk of lime
(iv)
aqueous solution of slaked lime
no
(i)
16. Which of the following elements does not form hydride by direct heating with
dihydrogen?
(i)
Be
(ii)
Mg
(iii)
Sr
(iv)
Ba
127 The s-Block Elements
17. The formula of soda ash is
(i)
Na2CO3.10H2O
(ii)
(iii)
Na2CO3.2H2O
Na2CO3.H2O
(iv)
Na2CO3
18. A substance which gives brick red flame and breaks down on heating to give
oxygen and a brown gas is
Magnesium nitrate
Calcium nitrate
(iii)
(iv)
Barium nitrate
Strontium nitrate
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(i)
(ii)
19. Which of the following statements is true about Ca(OH)2?
(i)
(ii)
It is used in the preparation of bleaching powder
It is a light blue solid
(iii)
(iv)
It does not possess disinfectant property.
It is used in the manufacture of cement.
20. A chemical A is used for the preparation of washing soda to recover ammonia.
When CO2 is bubbled through an aqueous solution of A, the solution turns
milky. It is used in white washing due to disinfectant nature. What is the
chemical formula of A?
(i) Ca (HCO3)2
(ii)
CaO
(iii)
(iv)
Ca(OH)2
CaCO3
21. Dehydration of hydrates of halides of calcium, barium and strontium i.e.,
CaCl26H2O, BaCl2.2H2O, SrCl 2.2H 2O, can be achieved by heating. These
become wet on keeping in air. Which of the following statements is correct
about these halides?
(i) act as dehydrating agent
can absorb moisture from air
Tendency to form hydrate decreases from calcium to barium
(iv)
All of the above
no
(ii)
(iii)
II. Multiple Choice Questions (Type-II)
In the following questions two or more options may be correct.
22. Metallic elements are described by their standard electrode potential, fusion
enthalpy, atomic size, etc. The alkali metals are characterised by which of the
following properties?
Exemplar Problems, Chemistry 128
(i)
High boiling point
(ii)
High negative standard electrode potential
(iii)
(iv)
High density
Large atomic size
23. Several sodium compounds find use in industries. Which of the following
compounds are used for textile industry?
Na2CO3
(ii)
(iii)
NaHCO3
NaOH
(iv)
NaCl
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(i)
24. Which of the following compounds are readily soluble in water?
(i)
BeSO4
(ii)
(iii)
MgSO4
BaSO4
(iv)
SrSO4
25. When Zeolite, which is hydrated sodium aluminium silicate is treated with
hard water, the sodium ions are exchanged with which of the following ion(s)?
+
(i)
(ii)
H ions
Mg2+ ions
(iii)
Ca ions
(iv)
SO24 – ions
2+
26. Identify the correct formula of halides of alkaline earth metals from the following.
(i)
(ii)
BaCl2.2H2O
BaCl2.4H2O
(iii)
CaCl2.6H2O
(iv)
SrCl2.4H2O
27. Choose the correct statements from the following.
Beryllium is not readily attacked by acids because of the presence of
an oxide film on the surface of the metal.
(ii)
(iii)
Beryllium sulphate is readily soluble in water as the greater hydration
2+
enthalpy of Be overcomes the lattice enthalpy factor.
Beryllium exhibits coordination number more than four.
(iv)
Beryllium oxide is purely acidic in nature.
no
(i)
28. Which of the following are the correct reasons for anomalous behaviour of lithium?
(i)
Exceptionally small size of its atom
(ii)
Its high polarising power
(iii)
It has high degree of hydration
(iv)
Exceptionally low ionisation enthalpy
129 The s-Block Elements
III. Short Answer Type
29. How do you account for the strong reducing power of lithium in aqueous
solution?
30. When heated in air, the alkali metals form various oxides. Mention the oxides
formed by Li, Na and K.
31. Complete the following reactions
(i)
+ H2O ⎯→
O 2–
2
O2– + H2O ⎯→
(ii)
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32. Lithium resembles magnesium in some of its properties. Mention two such
properties and give reasons for this resemblance.
33. Name an element from Group 2 which forms an amphoteric oxide and a water
soluble sulphate.
34. Discuss the trend of the following:
(i)
Thermal stability of carbonates of Group 2 elements.
(ii)
The solubility and the nature of oxides of Group 2 elements.
35. Why are BeSO4 and MgSO4 readily soluble in water while CaSO4, SrSO4 and
BaSO4 are insoluble?
36. All compounds of alkali metals are easily soluble in water but lithium
compounds are more soluble in organic solvents. Explain.
37. In the Solvay process, can we obtain sodium carbonate directly by treating
the solution containing (NH4) 2CO 3 with sodium chloride? Explain.
–
38. Write Lewis strucure of O2 ion and find out oxidation state of each oxygen
atom? What is the average oxidation state of oxygen in this ion?
39. Why do beryllium and magnesium not impart colour to the flame in the flame test?
40. What is the structure of BeCl2 molecule in gaseous and solid state?
IV. Matching Type
In the following questions more than one option of column I and II may be
correlated.
41. Match the elements given in Column I with the properties mentioned in Column II.
no
Column I
Column II
(i)
Li
(a) Insoluble sulphate
(ii)
Na
(b) Strongest monoacidic base
(iii)
Ca
(c) Most negative E
metals.
(iv)
Ba
(d) Insoluble oxalate
V
value among alkali
(e) 6s2 outer electronic configuration
Exemplar Problems, Chemistry 130
42.
Match the compounds given in Column I with their uses mentioned in Column II.
Column I
(i) CaCO3
(a)
Dentistry, ornamental work
(ii) Ca(OH)2
(b)
Manufacture of sodium carbonate from
caustic soda
(iii) CaO
(c)
Manufacture of high quality paper
(iv) CaSO4
(d)
Used in white washing
Match the elements given in Column I with the colour they impart to the
flame given in Column II.
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43.
Column II
Column I
Column II
(i) Cs
(a)
Apple green
(ii) Na
(b)
Violet
(iii) K
(c)
Brick red
(iv) Ca
(d)
Yellow
(v) Sr
(e)
Crimson red
(vi) Ba
(f)
Blue
V. Assertion and Reason Type
In the following questions a statement of Assertion (A) followed by a statement
of Reason (R) is given. Choose the correct option out of the choices given
below each question.
44. Assertion (A): The carbonate of lithium decomposes easily on heating to
form lithium oxide and CO2.
Reason (R) :
Lithium being very small in size polarises large carbonate
ion leading to the formation of more stable Li2O and CO2.
(i)
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct
(iv)
A is not correct but R is correct.
no
45. Assertion (A): Beryllium carbonate is kept in the atmosphere of carbon
dioxide.
Reason (R) :
Beryllium carbonate is unstable and decomposes to give
beryllium oxide and carbon dioxide.
(i)
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
131 The s-Block Elements
VI. Long Answer Type
46. The s-block elements are characterised by their larger atomic sizes, lower
ionisation enthalpies, invariable +1 oxidation state and solubilities of their
oxosalts.In the light of these features describe the nature of their oxides,
halides and oxosalts.
47. Present a comparative account of the alkali and alkaline earth metals with
respect to the following characteristics:
Tendency to form ionic / covalent compounds
(ii)
Nature of oxides and their solubility in water
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(i)
(iii)
Formation of oxosalts
(iv)
Solubility of oxosalts
(v)
Thermal stability of oxosalts
48. When a metal of group 1 was dissolved in liquid ammonia, the following
observations were obtained:
(i)
Blue solution was obtained initially.
(ii)
On concentrating the solution, blue colour changed to bronze colour.
How do you account for the blue colour of the solution? Give the name of the
product formed on keeping the solution for some time.
49. The stability of peroxide and superoxide of alkali metals increase as we go
down the group. Explain giving reason.
50. When water is added to compound (A) of calcium, solution of compound (B)
is formed. When carbon dioxide is passed into the solution, it turns milky
due to the formation of compound (C). If excess of carbon dioxide is passed
into the solution milkiness disappears due to the formation of compound
(D). Identify the compounds A, B, C and D. Explain why the milkiness
disappears in the last step.
51. Lithium hydride can be used to prepare other useful hydrides. Beryllium
hydride is one of them. Suggest a route for the preparation of beryllium hydride
starting from lithium hydride. Write chemical equations involved in the process.
no
52. An element of group 2 forms covalent oxide which is amphoteric in nature
and dissolves in water to give an amphoteric hydroxide. Identify the element
and write chemical reactions of the hydroxide of the element with an alkali
and an acid.
53. Ions of an element of group 1 participate in the transmission of nerve signals
and transport of sugars and aminoacids into cells. This element imparts yellow
colour to the flame in flame test and forms an oxide and a peroxide with
oxygen. Identify the element and write chemical reaction to show the formation
of its peroxide. Why does the element impart colour to the flame?
Exemplar Problems, Chemistry 132
ANSWERS
I. Multiple Choice Questions (Type-I)
1. (iv)
2. (i)
3. (iii)
4. (iv)
5. (i)
6. (i)
7. (i)
8. (iii)
9. (ii)
10. (i)
11. (i)
12. (i)
13. (ii)
14. (i)
15. (iii)
16. (i)
17. (iv)
18. (ii)
19. (i)
20. (iii)
21. (iv)
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II. Multiple Choice Questions (Type-II)
22. (ii), (iv)
23. (i), (iii)
24. (i), (ii)
26. (i), (iii)
27. (i), (ii)
28. (i), (ii)
25. (ii), (iii)
III. Short Answer Type
31.
(i)
O2–
+ 2H2O ⎯→ 2OH– + H2O2
2
(ii)
2O2 + 2H2O ⎯→ 2OH + H2O2 + O2
–
–
IV. Matching Type
41.
(i)→ (c),
(ii)→ (b),
(iii)→(d),
(iv)→(a), (e)
42.
(i)→ (c),
(ii) → (d),
(iii) → (b),
(iv) → (a)
43.
(i)→ (f),
(ii) → (d),
(iii) → (b),
(iv) → (c)
(v)→ (e),
(vi) → (a)
V. Assertion and Reason Type
44. (i)
45. (i)
VI. Long Answer Type
50.
Compound : A : CaO;
B : Ca (OH)2 ; C : CaCO3 ; D : Ca(HCO3)2
no
Ca(HCO3)2 is soluble in water. Hence, milkiness of solution disappears on
passing excess carbon dioxide into the solution of compound B.
51.
8 LiH + Al2Cl6 ⎯→ 2Li Al H4 + 6 LiCl
LiAl H4 + 2BeCl2 ⎯→ 2BeH2 + LiCl + AlCl3
52.
The element is beryllium
53.
The element is sodium.
133 The s-Block Elements
Unit
11
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THE p -BL
OCK ELEMENTS
-BLOCK
I. Multiple Choice Questions (Type-I)
1.
2.
(i)
(ii)
B
Al
(iii)
(iv)
Ga
In
Which of the following is a Lewis acid ?
(i)
(ii)
AlCl3
MgCl2
(iii)
(iv)
CaCl2
BaCl2
The geometry of a complex species can be understood from the knowledge of
type of hybridisation of orbitals of central atom. The hybridisation of orbitals
of central atom in [Be(OH)4] – and the geometry of the complex are respectively
(i)
(ii)
sp3 , tetrahedral
sp3 , square planar
(iii)
sp 3 d 2 , octahedral
(iv)
dsp2 , square planar
no
3.
The element which exists in liquid state for a wide range of temperature and
can be used for measuring high temperature is
4.
Which of the following oxides is acidic in nature?
(i)
(ii)
B2O3
Al2O3
(iii)
Ga2O3
(iv)
In2O3
6.
7.
8.
9.
The exhibition of highest co-ordination number depends on the availability of
vacant orbitals in the central atom. Which of the following elements is not likely
3–
to act as central atom in MF6 ?
(i)
B
(ii)
Al
(iii)
Ga
(iv)
In
Boric acid is an acid because its molecule
(i)
contains replaceable H+ ion
(ii)
gives up a proton
(iii)
accepts OH from water releasing proton
(iv)
combines with proton from water molecule
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5.
–
Catenation i.e., linking of similar atoms depends on size and electronic
configuration of atoms. The tendency of catenation in Group 14 elements
follows the order:
(i)
C > Si > Ge > Sn
(ii)
C >> Si > Ge ≈ Sn
(iii)
Si > C > Sn > Ge
(iv)
Ge > Sn > Si > C
Silicon has a strong tendency to form polymers like silicones. The chain length
of silicone polymer can be controlled by adding
(i)
MeSiCl 3
(ii)
Me2SiCl2
(iii)
Me3SiCl
(iv)
Me4Si
Ionisation enthalpy (Δi H1 kJ mol–1) for the elements of Group 13 follows the order.
(i)
B > Al > Ga > In > Tl
(ii)
B < Al < Ga < In < Tl
(iii)
B < Al > Ga < In > Tl
(iv)
B > Al < Ga > In < Tl
no
10. In the structure of diborane
(i)
(ii)
(iii)
(iv)
All hydrogen atoms lie in one plane and boron atoms lie in a plane
perpendicular to this plane.
2 boron atoms and 4 terminal hydrogen atoms lie in the same plane
and 2 bridging hydrogen atoms lie in the perpendicular plane.
4 bridging hydrogen atoms and boron atoms lie in one plane and two
terminal hydrogen atoms lie in a plane perpendicular to this plane.
All the atoms are in the same plane.
135 The p-Block Elements
11. A compound X, of boron reacts with NH3 on heating to give another compound
Y which is called inorganic benzene. The compound X can be prepared by
treating BF 3 with Lithium aluminium hydride. The compounds X and Y are
represented by the formulas.
(i)
B2H 6 , B3N3H6
(ii)
B2O 3, B3 N3 H6
(iii)
BF3, B3N3 H6
(iv)
B3N3H6 , B2H6
12. Quartz is extensively used as a piezoelectric material, it contains ___________.
Pb
(ii)
Si
(iii)
Ti
(iv)
Sn
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(i)
13. The most commonly used reducing agent is
(i)
AlCl3
(ii)
PbCl2
(iii)
SnCl4
(iv)
SnCl2
14. Dry ice is
(i)
Solid NH3
(ii)
Solid SO2
(iii)
Solid CO2
(iv)
Solid N2
15. Cement, the important building material is a mixture of oxides of several
elements. Besides calcium, iron and sulphur, oxides of elements of which of
the group (s) are present in the mixture?
(i)
group 2
(ii)
groups 2, 13 and 14
(iii)
groups 2 and 13
(iv)
groups 2 and 14
no
II. Multiple Choice Questions (Type-II)
In the following questions two or more options may be correct.
16. The reason for small radius of Ga compared to Al is _______.
(i)
poor screening effect of d and f orbitals
(ii)
increase in nuclear charge
Exemplar Problems, Chemistry 136
(iii)
presence of higher orbitals
(iv)
higher atomic number
17. The linear shape of CO2 is due to _________.
(i)
sp3 hybridisation of carbon
(ii)
sp hybridisation of carbon
(iii)
pπ – pπ bonding between carbon and oxygen
(iv)
sp2 hybridisation of carbon
18. Me3SiCl is used during polymerisation of organo silicones because
the chain length of organo silicone polymers can be controlled by adding
Me3SiCl
(ii)
Me3SiCl blocks the end terminal of silicone polymer
(iii)
Me3SiCl improves the quality and yield of the polymer
(iv)
Me3SiCl acts as a catalyst during polymerisation
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(i)
19. Which of the following statements are correct?
(i)
Fullerenes have dangling bonds
(ii)
Fullerenes are cage-like molecules
(iii)
Graphite is thermodynamically most stable allotrope of carbon
(iv)
Graphite is slippery and hard and therefore used as a dry lubricant in
machines
20. Which of the following statements are correct. Answer on the basis of Fig.11.1.
(i)
(ii)
(iii)
Out of six B-H bonds four B-H
bonds can be described in
terms of 3 centre 2 electron
bonds;
Fig. 11.1
The four terminal B-H bonds
are two centre-two electron regular bonds.
no
(iv)
The two birdged hydrogen
atoms and the two boron atoms
lie in one plane;
Out of six B–H bonds two
bonds can be described in
terms of 3 centre 2-electron
bonds.
21. Identify the correct resonance structures of carbon dioxide from the ones given
below :
(i)
O – C≡O
(ii)
O=C=O
+
O ≡ C–O
(iii)
–
(iv)
–
O – C ≡ O+
137 The p-Block Elements
III. Short Answer Type
22. Draw the structures of BCl 3.NH3 and AlCl3 (dimer).
23. Explain the nature of boric acid as a Lewis acid in water.
24. Draw the structure of boric acid showing hydrogen bonding. Which species
is present in water? What is the hybridisation of boron in this species?
25. Explain why the following compounds behave as Lewis acids?
(i)
BCl3
(ii)
AlCl3
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26. Give reasons for the following:
(i)
CCl4 is immiscible in water, whereas SiCl4 is easily hydrolysed.
(ii)
Carbon has a strong tendency for catenation compared to silicon.
27. Explain the following :
(i)
CO2 is a gas whereas SiO2 is a solid.
(ii)
Silicon forms SiF62– ion whereas corresponding fluoro compound of
carbon is not known.
28. The +1 oxidation state in group 13 and +2 oxidation state in group 14 becomes
more and more stable with increasing atomic number. Explain.
29. Carbon and silicon both belong to the group 14, but inspite of the
stoichiometric similarity, the dioxides, (i.e., carbon dioxide and silicon dioxide),
differ in their structures. Comment.
30. If a trivalent atom replaces a few silicon atoms in three dimensional network
of silicon dioxide, what would be the type of charge on overall structure?
31. When BCl3 is treated with water, it hydrolyses and forms [B[OH]4]– only whereas
3+
AlCl3 in acidified aqueous solution forms [Al (H2O) 6] ion. Explain what is the
hybridisation of boron and aluminium in these species?
32. Aluminium dissolves in mineral acids and aqueous alkalies and thus shows
amphoteric character. A piece of aluminium foil is treated with dilute
hydrochloric acid or dilute sodium hydroxide solution in a test tube and on
bringing a burning matchstick near the mouth of the test tube, a pop sound
indicates the evolution of hydrogen gas. The same activity when performed
with concentrated nitric acid, reaction doesn’t proceed. Explain the reason.
no
33. Explain the following :
(i)
Gallium has higher ionisation enthalpy than aluminium.
(ii)
Boron does not exist as B 3+ ion.
(iii)
Aluminium forms [AlF 6]3– ion but boron does not form [BF6]3– ion.
(iv)
PbX2 is more stable than PbX4.
(v)
Pb4+ acts as an oxidising agent but Sn2+ acts as a reducing agent.
(vi)
Electron gain enthalpy of chlorine is more negative as compared to fluorine.
(vii)
Tl (NO3)3 acts as an oxidising agent.
Exemplar Problems, Chemistry 138
(viii)
Carbon shows catenation property but lead does not.
(ix)
BF 3 does not hydrolyse.
(x)
Why does the element silicon, not form a graphite like structure whereas
carbon does.
34. Identify the compounds A, X and Z in the following reactions :
A + 2HCl + 5H2O ⎯→ 2NaCl + X
(i)
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Δ → HBO ⎯ ⎯⎯
Δ ⎯
X ⎯ ⎯⎯⎯
→Z
2
3 70K
>3 70K
35. Complete the following chemical equations :
Z + 3 LiAlH 4 ⎯→ X + 3 LiF + 3AlF3
X + 6H2O ⎯→ Y + 6H2
Δ
3X + 3O 2 ⎯⎯→
B2O 3 + 3H2 O
IV. Matching Type
In the following questions more than one correlation is possible between
options of Column I and Column II. Make as many correlations as you can.
36. Match the species given in Column I with the properties mentioned in
Column II.
Column I
–
Column II
(i) BF 4
(a)
Oxidation state of central atom is +4
(ii) AlCl3
(b)
Strong oxidising agent
(iii) SnO
(c)
Lewis acid
(iv) PbO2
(d)
Can be further oxidised
(e)
Tetrahedral shape
37. Match the species given in Column I with properties given in Column II.
no
Column I
Column II
(i) Diborane
(a) Used as a flux for soldering metals
(ii) Galluim
(b) Crystalline form of silica
(iii) Borax
(c) Banana bonds
(iv) Aluminosilicate
(d) Low melting, high boiling, useful for
measuring high temperatures
(v) Quartz
(e) Used as catalyst in petrochemical
industries
139 The p-Block Elements
38. Match the species given in Column I with the hybridisation given in Column II.
Column I
Column II
(i)
Boron in [B(OH)4]–
(a) sp2
(ii)
Aluminium in [Al(H2O)6]3+
(b) sp3
(iii)
Boron in B2H 6
(c)
(iv)
Carbon in Buckminsterfullerene
(v)
Silicon in SiO44–
(vi)
Germanium in [GeCl6]
sp3d2
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2–
V. Assertion and Reason Type
In the following questions a statement of Assertion (A) followed by a statement
of Reason (R) is given. Choose the correct option out of the choices given
below each question.
39. Assertion (A): If aluminium atoms replace a few silicon atoms in three
dimensional network of silicon dioxide, the overall structure
acquires a negative charge.
Reason (R) :
Aluminium is trivalent while silicon is tetravalent.
(i)
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct
(iv)
A is not correct but R is correct.
40. Assertion (A): Silicons are water repelling in nature.
Reason (R) :
Silicons are organosilicon polymers, which have (–R 2SiO–) as
repeating unit.
(i)
A and R both are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
A and R both are not true.
(iv)
A is not true but R is true.
no
VI. Long Answer Type
41. Describe the general trends in the following properties of the elements in
Groups 13 and 14.
(i)
Atomic size
(ii)
Ionisation enthalpy
(iii)
Metallic character
(iv)
Oxidation states
(v)
Nature of halides
Exemplar Problems, Chemistry 140
42. Account for the following observations:
(i)
AlCl 3 is a Lewis acid
(ii)
Though fluorine is more electronegative than chlorine yet BF3 is a weaker
Lewis acid than BCl3
(iii)
PbO 2 is a stronger oxidising agent than SnO2
(iv)
The +1 oxidation state of thallium is more stable than its +3 state.
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43. When aqueous solution of borax is acidified with hydrochloric acid, a white
crystalline solid is formed which is soapy to touch. Is this solid acidic or basic
in nature? Explain.
44. Three pairs of compounds are given below. Identify that compound in each of
the pairs which has group 13 element in more stable oxidation state. Give
reason for your choice. State the nature of bonding also.
(i)
TlCl 3, TlCl
(ii)
AlCl 3 , AlCl
(iii)
InCl 3, InCl
45. BCl3 exists as monomer whereas AlCl3 is dimerised through halogen bridging.
Give reason. Explain the structure of the dimer of AlCl3 also.
46. Boron fluoride exists as BF3 but boron hydride doesn’t exist as BH3. Give
reason. In which form does it exist? Explain its structure.
47. (i)
(ii)
What are silicones? State the uses of silicones.
What are boranes? Give chemical equation for the preparation of diborane.
48. A compound (A) of boron reacts with NMe3 to give an adduct (B) which on
hydrolysis gives a compound (C) and hydrogen gas. Compound (C) is an acid.
Identify the compounds A, B and C. Give the reactions involved.
49. A nonmetallic element of group 13, used in making bullet proof vests is
extremely hard solid of black colour. It can exist in many allotropic forms and
has unusually high melting point. Its trifluoride acts as Lewis acid towards
ammonia. The element exihibits maximum covalency of four. Identify the
element and write the reaction of its trifluoride with ammonia. Explain why
does the trifluoride act as a Lewis acid.
no
50. A tetravalent element forms monoxide and dioxide with oxygen. When air is
passed over heated element (1273 K), producer gas is obtained. Monoxide of
the element is a powerful reducing agent and reduces ferric oxide to iron.
Identify the element and write formulas of its monoxide and dioxide. Write
chemical equations for the formation of producer gas and reduction of ferric
oxide with the monoxide.
141 The p-Block Elements
ANSWERS
I. Multiple Choice Questions (Type-I)
1. (iii)
2. (i)
3. (i)
4. (i)
5. (i)
6. (iii)
7. (ii)
8. (iii)
9. (iv)
10. (ii)
11. (i)
12. (ii)
13. (iv)
14. (iii)
15. (ii)
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II. Multiple Choice Questions (Type-II)
16. (i), (ii)
17. (ii), (iii)
18. (i), (ii)
19. (ii), (iii)
20. (i), (ii), (iv)
21. (ii), (iv)
III. Short Answer Type
23.
Boric acid acts as Lewis acid in water by accepting a pair of electrons
from a hydroxyl ion :
B (OH) 3 + 2HOH ⎯→ [B(OH)4] – + H3O +
24.
Species present in water is [B(OH)4]– . Boron is sp3 hybridised.
25.
BCl3 and AlCl3 being electron deficient due to incomplete octet of central
metal atom behave as Lewis acids.
26.
CCl4 is a covalent compound. Hence, insoluble in water whereas SiCl4 is
soluble because Si atom in SiCl4 can accomodate the lone pair of electrons
obtained from oxygen atom of water molecule in d-orbitals.
27.
(i)
Very high Si-O bond enthalpy and ionic character of Si-O bond.
(ii)
Vacant 3d orbitals are available on Si atom to accomodate electrons
and expand coordination number upto 6.
[Hint : In CO 2 , carbon is sp hybridised and it is a linear molecule. In
SiO2, Si is tetrahedrally bonded to four oxygen atoms.]
30.
Negative
32.
[Hint : Conc. HNO3 renders aluminium passive by forming a protective
oxide layer on the surface.]
no
29.
34.
A
:
Na2B4O7 (Borax)
X
:
Z
:
A
:
BF3
H3BO3
X
:
B2H6
B2O3
Y
;
H3BO3
Exemplar Problems, Chemistry 142
35.
IV. Matching Type
36.
(i) → (e)
(ii) → (c)
(iii) → (d)
(iv) → (a), (b)
37.
(i)→ (c)
(ii)→ (d)
(iii)→(a)
(iv)→(e)
(v)→(b)
38.
(i)→ (b),
(ii) → (c),
(iii) → (b),
(iv) → (a)
(v)→(b)
(vi)→(c)
V. Assertion and Reason Type
40. (ii)
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39. (i)
VI. Long Answer Type
45.
[Hint : Absence of d-orbitals in boron.]
48.
A = B 2H6,
C = B(OH)3 i.e. H3BO3.
no
B = BH3.NMe3,
143 The p-Block Elements
Unit
12
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ORG
ANIC CHEMIS
TRY
ORGANIC
CHEMISTRY
SOME
BA
PRINCIPLES
SOME B
BA
ASIC
SIC PRINCIPLE
PRINCIPLESS
AND
SS
TECHNIQUES
AND TECHNIQUE
TECHNIQUE
TECHNIQUES
I. Multiple Choice Questions (Type-I)
1.
2.
(i)
3-Ethyl-4, 4-dimethylheptane
(ii)
4,4-Dimethyl-3-ethylheptane
(iii)
5-Ethyl-4, 4-dimethylheptane
(iv)
4,4-Bis(methyl)-3-ethylheptane
The IUPAC name for
(i)
1-hydroxypentane-1,4-dione
(ii)
1,4-dioxopentanol
(iii)
1-carboxybutan-3-one
(iv)
4-oxopentanoic acid
The IUPAC name for
no
3.
Which of the following is the correct IUPAC name?
is ________.
5.
6.
(ii)
1-Chloro-4-methyl-2-nitrobenzene
(iii)
2-Chloro-1-nitro-5-methylbenzene
(iv)
m-Nitro-p-chlorotoluene
Electronegativity of carbon atoms depends upon their state of hybridisation.
In which of the following compounds, the carbon marked with asterisk is
most electronegative?
(i)
CH3 – CH2 – *CH2 –CH3
(ii)
CH3 – *CH = CH – CH3
(iii)
CH3 – CH2 – C ≡ *CH
(iv)
CH3 – CH2 – CH = *CH2
In which of the following, functional group isomerism is not possible?
(i)
Alcohols
(ii)
Aldehydes
(iii)
Alkyl halides
(iv)
Cyanides
The fragrance of flowers is due to the presence of some steam volatile organic
compounds called essential oils. These are generally insoluble in water at
room temperature but are miscible with water vapour in vapour phase. A
suitable method for the extraction of these oils from the flowers is:
(i)
Distillation
(ii)
Crystallisation
(iii)
Distillation under reduced pressure
(iv)
Steam distillation
During hearing of a court case, the judge suspected that some changes in the
documents had been carried out. He asked the forensic department to check
the ink used at two different places. According to you which technique can
give the best results?
(i)
Column chromatography
(ii)
Solvent extraction
(iii)
Distillation
no
7.
1-Chloro-2-nitro-4-methylbenzene
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4.
(i)
(iv)
8.
Thin layer chromatography
The principle involved in paper chromatography is
(i)
Adsorption
(ii)
Partition
(iii)
Solubility
(iv)
Volatility
145 Organic Chemistry – Some Basic Principles and Techniques
9. What is the correct order of decreasing stability of the following cations.
I.
(i)
II > I > III
(ii)
II > III > I
(iii)
III > I > II
(iv)
I > II > III
II.
is ___________.
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10. Correct IUPAC name for
III.
(i)
2- ethyl-3-methylpentane
(ii)
3,4- dimethylhexane
(iii)
2-sec-butylbutane
(iv)
2, 3-dimethylbutane
11. In which of the following compounds the carbon marked with asterisk is
expected to have greatest positive charge?
(i)
*CH3—CH2—Cl
(ii)
*CH3—CH2—Mg+Cl–
(iii)
*CH3—CH2—Br
(iv)
*CH3—CH2—CH3
12. Ionic species are stabilised by the dispersal of charge. Which of the
following carboxylate ion is the most stable?
(i)
(ii)
no
(iii)
(iv)
13. Electrophilic addition reactions proceed in two steps. The first step
involves the addition of an electrophile. Name the type of intermediate
formed in the first step of the following addition reaction.
H3C—HC = CH2 + H + ⎯→?
Exemplar Problems, Chemistry 146
(i)
2° Carbanion
(ii)
1° Carbocation
(iii)
2° Carbocation
(iv)
1° Carbanion
14. Covalent bond can undergo fission in two different ways. The correct
representation involving a heterolytic fission of CH3—Br is
(i)
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(ii)
(iii)
(iv)
15. The addition of HCl to an alkene proceeds in two steps. The first step is the
portion which can be shown as
attack of H+ ion to
(i)
(ii)
(iii)
(iv)
All of these are possible
II. Multiple Choice Questions (Type-II)
In the following questions two or more options may be correct.
16. Which of the following compounds contain all the carbon atoms in the same
hybridisation state?
H—C ≡ C—C ≡ C—H
(ii)
CH3—C ≡ C—CH3
(iii)
CH2 = C = CH2
(iv)
CH2 = CH—CH = CH 2
no
(i)
17. In which of the following representations given below spatial arrangement of
group/ atom different from that given in structure ‘A’?
(A)
147 Organic Chemistry – Some Basic Principles and Techniques
(i)
(ii)
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(iii)
(iv)
18. Electrophiles are electron seeking species. Which of the following groups
contain only electrophiles?
(i)
BF3 , NH3 , H2O
(ii)
AlCl3, SO3 , NO+2
(iii)
NO2 , CH3 , CH 3 –
(iv)
C2H5 ,
+
+
–
=O
+
, C2H5
Note : Consider the following four compounds for answering questions 19
and 20.
I.
II.
no
III.
IV.
19. Which of the following pairs are position isomers?
(i)
I and II
Exemplar Problems, Chemistry 148
(ii)
II and III
(iii)
II and IV
(iv)
III and IV
20. Which of the following pairs are not functional group isomers?
(i)
II and III
(ii)
II and IV
(iii)
I and IV
(iv)
I and II
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21. Nucleophile is a species that should have
(i)
a pair of electrons to donate
(ii)
positive charge
(iii)
negative charge
(iv)
electron deficient species
22. Hyperconjugation involves delocalisation of ___________.
(i)
electrons of carbon-hydrogen σ bond of an alkyl group directly attached
to an atom of unsaturated system.
(ii)
electrons of carbon-hydrogen σ bond of alkyl group directly attached to
the positively charged carbon atom.
(iii)
π-electrons of carbon-carbon bond
(iv)
lone pair of electrons
III. Short Answer Type
Note : Consider structures I to VII and answer the questions 23–26.
I.
CH3—CH2—CH2—CH2—OH
II.
no
III.
IV.
149 Organic Chemistry – Some Basic Principles and Techniques
V.
CH3—CH 2—O—CH2—CH3
VI.
CH3—O—CH2—CH2—CH3
VII.
23. Which of the above compounds form pairs of metamers?
24. Identify the pairs of compounds which are functional group isomers.
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25. Identify the pairs of compounds that represents position isomerism.
26. Identify the pairs of compounds that represents chain isomerism.
27. For testing halogens in an organic compound with AgNO3 solution, sodium
extract (Lassaigne’s test) is acidified with dilute HNO3. What will happen if a
student acidifies the extract with dilute H2SO4 in place of dilute HNO 3?
28. What is the hybridisation of each carbon in H 2C = C = CH2.
29. Explain, how is the electronegativity of carbon atoms related to their state of
hybridisation in an organic compound?
30. Show the polarisation of carbon-magnesium bond in the following structure.
CH3—CH2—CH2—CH2—Mg—X
31. Compounds with same molecular formula but differing in their structures are
said to be structural isomers. What type of structural isomerism is shown by
CH 3—S—CH2—CH2—CH3 and
no
32. Which of the following selected chains is correct to name the given compound
according to IUPAC system.
Exemplar Problems, Chemistry 150
33. In DNA and RNA, nitrogen atom is present in the ring system. Can Kjeldahl
method be used for the estimation of nitrogen present in these? Give reasons.
34. If a liquid compound decomposes at its boiling point, which method (s) can
you choose for its purification. It is known that the compound is stable at low
pressure, steam volatile and insoluble in water.
Note : Answer the questions 35 to 38 on the basis of information given below:
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“Stability of carbocations depends upon the electron releasing inductive effect
of groups adjacent to positively charged carbon atom involvement of
neighbouring groups in hyperconjugation and resonance.”
and predict which
35. Draw the possible resonance structures for
of the structures is more stable. Give reason for your answer.
36. Which of the following ions is more stable? Use resonance to explain your
answer.
37. The structure of triphenylmethyl cation is given below. This is very stable and
some of its salts can be stored for months. Explain the cause of high stability
of this cation.
38. Write structures of various carbocations that can be obtained from
2-methylbutane. Arrange these carbocations in order of increasing stability.
no
39. Three students, Manish, Ramesh and Rajni were determining the extra
elements present in an organic compound given by their teacher. They
prepared the Lassaigne’s extract (L.E.) independently by the fusion of the
compound with sodium metal. Then they added solid FeSO4 and dilute
sulphuric acid to a part of Lassaigne’s extract. Manish and Rajni obtained
prussian blue colour but Ramesh got red colour. Ramesh repeated the test
with the same Lassaigne’s extract, but again got red colour only. They were
surprised and went to their teacher and told him about their observation.
Teacher asked them to think over the reason for this. Can you help them by
giving the reason for this observation. Also, write the chemical equations to
explain the formation of compounds of different colours.
151 Organic Chemistry – Some Basic Principles and Techniques
40. Name the compounds whose line formulae are given below :
(i)
(ii)
41. Write structural formulae for compounds named as(a) 1-Bromoheptane
(b) 5-Bromoheptanoic acid
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42. Draw the resonance structures of the following compounds;
(i)
(ii)
CH2 = CH—CH = CH2
(iii)
43. Identify the most stable species in the following set of ions giving reasons :
(i)
(ii)
44. Give three points of differences between inductive effect and resonance effect.
45. Which of the following compounds will not exist as resonance hybrid. Give
reason for your answer :
(i) CH 3OH
(ii) R—CONH2
(iii) CH 3CH = CHCH2NH2
46. Why does SO 3 act as an electrophile?
47. Resonance structures of propenal are given below. Which of these resonating
structures is more stable? Give reason for your answer.
no
48. By mistake, an alcohol (boiling point 97°C) was mixed with a hydrocarbon
(boiling point 68°C). Suggest a suitable method to separate the two
compounds. Explain the reason for your choice.
49. Which of the two structures (A) and (B) given below is more stabilised by
resonance? Explain.
CH3COOH
and
(A)
Exemplar Problems, Chemistry 152
(B)
IV. Matching Type
In the following questions more than one correlation is possible between
options of Column I and Column II. Make as many correlations as you can.
50. Match the type of mixture of compounds in Column I with the technique of
separation/purification given in Column II.
Column I
Column II
(a)
Steam distillation
(ii) Liquid that decomposes at its
boiling point
(b)
Fractional distillation
(iii) Steam volatile liquid
(c)
Simple distillation
(iv) Two liquids which have boiling
points close to each other
(d)
Distillation under reduced
pressure
(v) Two liquids with large difference in
boiling points.
(e)
Crystallisation
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(i) Two solids which have different
solubilities in a solvent and which
do not undergo reaction when
dissolved in it.
51. Match the terms mentioned in Column I with the terms in Column II.
Column I
Column II
(a)
Cyclohexane and 1- hexene
(ii) Nucleophile
(b)
Conjugation of electrons of C–H
σ bond with empty p-orbital present
at adjacent positively charged
carbon.
(iii) Hyperconjugation
(c)
sp2 hybridised carbon with empty
p-orbital
(iv) Isomers
(d)
Ethyne
(v) sp hybridisation
(e)
Species that can receive a pair of
electrons
(f)
Species that can supply a pair of
electrons
no
(i) Carbocation
(vi) Electrophile
52. Match Column I with Column II.
Column I
(i) Dumas method
Column II
(a) AgNO3
153 Organic Chemistry – Some Basic Principles and Techniques
(ii) Kjeldahl’s method
(b) Silica gel
(iii) Carius method
(c) Nitrogen gas
(iv) Chromatography
(d) Free radicals
(v) Homolysis
(e) Ammonium sulphate
53. Match the intermediates given in Column I with their probable structure in
Column II.
Column II
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Column I
(i) Free radical
(a) Trigonal planar
(ii) Carbocation
(b) Pyramidal
(iii) Carbanion
(c) Linear
54. Match the ions given in Column I with their nature given in Column II.
Column I
Column II
(i)
(a) Stable due to resonance
(ii)
(b) Destabilised due to inductive effect
(iii)
(c) Stabilised by hyperconjugation
(iv)
(d) A secondary carbocation
V. Assertion and Reason Type
no
In the following questions a statement of Assertion (A) followed by a statement
of Reason (R) is given. Choose the correct option out of the choices given
below each question.
55. Assertion (A) : Simple distillation can help in separating a mixture of
propan-1-ol (boiling point 97°C) and propanone (boiling point
56°C).
Reason (R) :
Liquids with a difference of more than 20°C in their boiling
points can be separated by simple distillation.
Exemplar Problems, Chemistry 154
(i)
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
56. Assertion (A) : Energy of resonance hybrid is equal to the average of energies
of all canonical forms.
Reason (R) :
Resonance hybrid cannot be presented by a single structure.
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
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(i)
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
57. Assertion (A) : Pent- 1- ene and pent- 2- ene are position isomers.
Reason (R) :
Position isomers differ in the position of functional group or
a substituent.
(i)
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
58. Assertion (A) : All the carbon atoms in H2C = C = CH2 are sp2 hybridised
Reason (R) :
In this molecule all the carbon atoms are attached to each other
by double bonds.
(i)
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
59. Assertion (A) : Sulphur present in an organic compound can be estimated
quantitatively by Carius method.
Reason (R) :
Sulphur is separated easily from other atoms in the molecule
and gets precipitated as light yellow solid.
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
no
(i)
60. Assertion (A): Components of a mixture of red and blue inks can be
separated by distributing the components between stationary
and mobile phases in paper chromatography.
155 Organic Chemistry – Some Basic Principles and Techniques
Reason (R) :
The coloured components of inks migrate at different rates
because paper selectively retains different components
according to the difference in their partition between the two
phases.
(i)
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
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VI. Long Answer Type
61. What is meant by hybridisation? Compound CH2 = C = CH2 contains sp or sp2
hybridised carbon atoms. Will it be a planar molecule?
62. Benzoic acid is a organic compound. Its crude sample can be purified by
crystallisation from hot water. What characteristic differences in the properties
of benzoic acid and the impurity make this process of purification suitable?
63. Two liquids (A) and (B) can be separated by the method of fractional distillation.
The boiling point of liquid (A) is less than boiling point of liquid (B). Which of
the liquids do you expect to come out first in the distillate? Explain.
64. You have a mixture of three liquids A, B and C. There is a large difference in
the boiling points of A and rest of the two liquids i.e., B and C. Boiling point of
liquids B and C are quite close. Liquid A boils at a higher temperature than B
and C and boiling point of B is lower than C. How will you separate the
components of the mixture. Draw a diagram showing set up of the apparatus
for the process.
65. Draw a diagram of bubble plate type fractionating column. When do we require
such type of a column for separating two liquids. Explain the principle involved
in the separation of components of a mixture of liquids by using fractionating
column. What industrial applications does this process have?
no
66. A liquid with high boiling point decomposes on simple distillation but it can
be steam distilled for its purification. Explain how is it possible?
Exemplar Problems, Chemistry 156
ANSWERS
I. Multiple Choice Questions (Type-I)
1. (ii)
2. (iv)
3. (ii)
4. (iii)
5. (iii)
6. (iv)
7. (iv)
8. (ii)
9. (i)
10. (ii)
11. (i)
12. (iv)
13. (iii)
14. (ii)
15. (ii)
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II. Multiple Choice Questions (Type-II)
16. (i), (iv)
17. (i), (iii), (iv)
18. (ii), (iii)
19. (ii)
20. (i), (iii)
21. (i), (iii)
22. (i), (ii)
III. Short Answer Type
27.
White ppt. of Ag2SO4 will be formed.
29.
Electronegativity increases with increasing ‘s’ character.
sp3 < sp2 < sp
. Since electronegativity of carbon is more
30.
than magnesium it will behave as
.
31.
Metamerism.
32.
The four carbon chain. Selected chain should have maximum number of
functional groups.
33.
DNA and RNA have nitrogen in the heterocyclic rings. Nitrogen present in
rings, azo groups and nitro groups cannot be removed as ammonia.
35.
I.
II.
Structure II is more stable because every atom has complete octet.
Structure I is more stable due to resonance. (See resonance structure ‘A’
and ‘B’). No resonance is possible in structure II.
no
36.
157 Organic Chemistry – Some Basic Principles and Techniques
Stabilised due to nine possible canonical structures.
38.
Four possible carbocations are
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37.
Order of increasing stability
39.
I < IV < II < III
In Lassaigne’s test SCN – ions are formed due to the presence of sulphur
and nitrogen both. These give red colour with Fe3+ ions. This happens
when fusion is not carried out in the excess of sodium. With excess of
sodium the thiocyanate ion, if formed, is decomposed as follows:
NaSCN + 2Na ⎯→ NaCN + Na2S
40. (i) 3-Ethyl-4-methylheptan-5-en-2-one
(ii) 3-Nitrocyclohex-1-ene.
41. (a) CH3—CH2—CH2—CH2—CH2—CH2—CH2Br
(b)
no
42. (i)
(ii)
(iii)
Exemplar Problems, Chemistry 158
43.
(i)
, The replacement of hydrogen by bromine increases positive
charge on carbon atom and destabilises the species.
(ii)
is most stable because electronegativity of chlorine is more
than hydrogen. On replacing hydrogen by chlorine, negative charge
on carbon is reduced and species is stabilised.
44.
Inductive effect
Resonance effect
Use σ-electrons
(a)
Use π- electrons or lone pair of
electrons
(ii)
Move up to 3-carbon atoms
(b)
All along the length of
conjugated system
(iii)
Slightly displaced electrons
(c)
Complete transfer of electrons
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(i)
45.
CH3OH; Any possible contributing structure will have charge separation
and incomplete octet of electrons on atoms. So the structure will be unstable
due to high energy. e.g.,
.
46.
Three highly electronegative oxygen atoms are attached to sulphur atom.
It makes sulphur atom electron deficient. Due to resonance also, sulphur
acquires positive charge. Both these factors make SO 3 an electrophile.
47.
I > II
48.
Simple distillation can be used because the two compounds have a
difference of more than 20° in their boiling points and both the liquids
can be distilled without any decomposition.
49.
Resonating structures are as follows:
no
(A)
(B)
Structure ‘B’ is more stabilised as it does not involve charge separation.
159 Organic Chemistry – Some Basic Principles and Techniques
IV. Matching Type
50.
(i) → (e)
(ii) → (d)
(iii) → (a)
(iv) → (b)
(v) → (c)
51.
(i) → (c)
(ii) → (f )
(iii) → (b)
(iv) → (a)
(v) → (d)
(iv) → (b)
(v) → (d)
(iii) → (b)
(iv) → (c), (d)
(vi) → (e)
52.
(i) → (c)
(ii) → (e)
(iii) → (a)
53.
(i) → (a),
(ii) → (a)
(iii) → (b)
54.
(i) → (a), (b), (d)
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(ii) → (b)
V. Assertion and Reason Type
55. (i)
56. (iv)
57. (i)
58. (iv)
59. (iii)
60. (i)
VI. Long Answer Type
61.
No. It is not a planar molecule.
no
Central carbon atom is sp hybridised and its two unhybridised p-orbitals
are perpendicular to each other. The p-orbitals in one plane overlap with
one of the p-orbital of left terminal carbon atom and the p-orbital in other
plane overlaps with p-orbital of right side terminal carbon atom. This
fixes the position of two terminal carbon atoms and the hydrogen atoms
attached to them in planes perpendicular to each other. Due to this the
pair of hydrogen atoms attached to terminal carbon atoms are present in
different planes.
Exemplar Problems, Chemistry 160
Unit
13
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HYDR
OC
ARBONS
YDROC
OCARBONS
I. Multiple Choice Questions (Type-I)
1.
(A) n–butane
(B) 2–methylbutane
(C) n-pentane
(D) 2,2–dimethylpropane
(i)
A>B>C>D
(ii)
B>C>D>A
(iii)
D>C>B>A
(iv)
C>B>D>A
Arrange the halogens F2 , Cl 2 , Br2 , I2 , in order of their increasing reactivity
with alkanes.
(i)
I 2 < Br2 < Cl2 < F2
(ii)
Br 2 < Cl2 < F2 < I2
(iii)
F2 < Cl2 < Br2 < I2
(iv)
Br 2 < I 2 < Cl2 < F2
no
2.
Arrange the following in decreasing order of their boiling points.
3.
The increasing order of reduction of alkyl halides with zinc and dilute HCl is
(i)
R–Cl < R–I < R–Br
ii)
R–Cl < R–Br < R–I
(iii)
R–I < R–Br < R–Cl
(iv)
R–Br < R–I < R–Cl
The correct IUPAC name of the following alkane is
(i)
3,6 – Diethyl – 2 – methyloctane
(ii)
5 – Isopropyl – 3 – ethyloctane
(iii)
3 – Ethyl – 5 – isopropyloctane
(iv)
3 – Isopropyl – 6 – ethyloctane
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4.
5.
The addition of HBr to 1-butene gives a mixture of products A, B and C
(A)
(B)
(C)
The mixture consists of
6.
(i)
A and B as major and C as minor products
(ii)
B as major, A and C as minor products
(iii)
B as minor, A and C as major products
(iv)
A and B as minor and C as major products
Which of the following will not show geometrical isomerism?
(i)
(ii)
no
(iii)
(iv)
Exemplar Problems, Chemistry 162
7. Arrange the following hydrogen halides in order of their decreasing reactivity
with propene.
(i)
HCl > HBr > HI
(ii)
HBr > HI > HCl
(iii)
HI > HBr > HCl
(iv)
HCl > HI > HBr
8. Arrange the following carbanions in order of their decreasing stability.
(A) H3C – C ≡ C
–
–
(C)
A>B>C
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(i)
(B) H – C ≡ C
(ii)
B>A>C
(iii)
C>B>A
(iv)
C>A>B
9. Arrange the following alkyl halides in decreasing order of the rate of
β– elimination reaction with alcoholic KOH.
(B) CH3—CH2—Br
(A)
(i)
A>B>C
(ii)
C>B>A
(iii)
B>C>A
(iv)
A>C>B
(C) CH 3—CH2—CH2—Br
10. Which of the following reactions of methane is incomplete combustion:
(i)
Cu/523 K/100 atm
2CH4 + O2 ⎯⎯⎯⎯⎯⎯⎯⎯
→ 2CH3OH
(iii)
Mo2O3
CH4 + O 2 ⎯⎯⎯⎯
→ HCHO + H2O
CH4 + O2 ⎯⎯→ C(s) + 2H2O (l)
(iv)
CH4 + 2O2 ⎯⎯→ CO2 (g) + 2H2O (l)
(ii)
no
II. Multiple Choice Questions (Type-II)
In the following questions two or more options may be correct.
11. Some oxidation reactions of methane are given below. Which of them is/are
controlled oxidation reactions?
(i)
(ii)
CH4 (g) + 2O2 (g) ⎯⎯→ CO2 (g) + 2H2O (l)
CH4 (g) + O2 (g) ⎯⎯→ C (s) + 2H2O (l)
(iii)
Mo2O3
CH4 (g) + O2 (g) ⎯⎯⎯⎯
→ HCHO + H2O
163
Hydrocarbons
(iv)
Cu/523 /100 atm
2CH4 (g) + O2 (g) ⎯⎯⎯⎯⎯⎯⎯
→ 2CH3OH
12. Which of the following alkenes on ozonolysis give a mixture of ketones only?
(i)
CH3—CH
CH—CH3
(ii)
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(iii)
(iv)
13. Which are the correct IUPAC names of the following compound?
(i)
(ii)
5– Butyl – 4– isopropyldecane
5– Ethyl – 4– propyldecane
(iii)
(iv)
5– sec-Butyl – 4– iso-propyldecane
4–(1-methylethyl)– 5 – (1-methylpropyl)-decane
14. Which are the correct IUPAC names of the following compound?
5 – (2′, 2′–Dimethylpropyl)-decane
(ii)
4 – Butyl – 2,2– dimethylnonane
no
(i)
(iii)
2,2– Dimethyl – 4– pentyloctane
(iv)
5 – neo-Pentyldecane
15. For an electrophilic substitution reaction, the presence of a halogen atom in
the benzene ring _______.
(i)
deactivates the ring by inductive effect
(ii)
deactivates the ring by resonance
Exemplar Problems, Chemistry 164
(iii)
increases the charge density at ortho and para position relative to meta
position by resonance
(iv)
directs the incoming electrophile to meta position by increasing the
charge density relative to ortho and para position.
16. In an electrophilic substitution reaction of nitrobenzene, the presence of nitro
group ________.
(i)
(ii)
(iii)
activates the ring by inductive effect.
decreases the charge density at ortho and para position of the ring
relative to meta position by resonance.
increases the charge density at meta position relative to the ortho and
para positions of the ring by resonance.
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(iv)
deactivates the ring by inductive effect.
17. Which of the following are correct?
(i)
is more stable than CH 3— CH ⊕
CH 3—O— CH⊕
2
2
(ii)
(CH 3)2 CH ⊕ is less stable than CH3—CH2— CH⊕
2
(iii)
CH 2
CH— CH ⊕
is more stable than CH3—CH2— CH ⊕
2
2
(iv)
CH 2
CH⊕ is more stable than CH 3— CH ⊕2
18. Four structures are given in options (i) to (iv). Examine them and select the
aromatic structures.
(i)
(ii)
(iii)
(iv)
19. The molecules having dipole moment are __________.
2,2-Dimethylpropane
(ii)
trans-Pent-2-ene
(iii)
cis-Hex-3-ene
(iv)
2, 2, 3, 3 - Tetramethylbutane.
no
(i)
III. Short Answer Type
20. Why do alkenes prefer to undergo electrophilic addition reaction while arenes
prefer electrophilic substitution reactions? Explain.
21. Alkynes on reduction with sodium in liquid ammonia form trans alkenes.
Will the butene thus formed on reduction of 2-butyne show the geometrical
isomerism?
165
Hydrocarbons
22. Rotation around carbon-carbon single bond of ethane is not completely free.
Justify the statement.
23. Draw Newman and Sawhorse projections for the eclipsed and staggered
conformations of ethane. Which of these conformations is more stable and why?
24. The intermediate carbocation formed in the reactions of HI, HBr and HCl with
propene is the same and the bond energy of HCl, HBr and HI is 430.5 kJ mol–1,
363.7 kJ mol –1 and 296.8 kJ mol–1 respectively. What will be the order of
reactivity of these halogen acids?
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25. What will be the product obtained as a result of the following reaction and why?
26. How will you convert benzene into (i) p – nitrobromobenzene
(ii) m – nitrobromobenzene
27. Arrange the following set of compounds in the order of their decreasing relative
reactivity with an electrophile.Give reason.
28. Despite their - I effect, halogens are o- and p-directing in haloarenes. Explain.
29. Why does presence of a nitro group make the benzene ring less reactive in
comparison to the unsubstituted benzene ring. Explain.
30. Suggest a route for the preparation of nitrobenzene starting from acetylene?
31. Predict the major product (s) of the following reactions and explain their formation.
(Ph-CO-O)
H 3C—CH
2 →
CH2 ⎯⎯⎯
⎯⎯⎯
HB
r
H 3C—CH
HBr
CH2 ⎯⎯
⎯
→
no
32. Nucleophiles and electrophiles are reaction intermediates having electron rich
and electron deficient centres respectively. Hence, they tend to attack electron
deficient and electron rich centres respectively. Classify the following species
as electrophiles and nucleophiles.
(i)
H 3CO–
(v)
(H 3C)3C
(ii)
+
(vi)
(iii)
Br
–
(vii)
(iv)
H 3COH
(viii) R–NH–R
33. The relative reactivity of 1°, 2°, 3° hydrogen’s towards chlorination is 1 : 3.8 : 5.
Calculate the percentages of all monochlorinated products obtained from
2-methylbutane.
Exemplar Problems, Chemistry 166
34. Write the structures and names of products obtained in the reactions of sodium
with a mixture of 1-iodo-2-methylpropane and 2-iodopropane.
35. Write hydrocarbon radicals that can be formed as intermediates during
monochlorination of 2-methylpropane? Which of them is more stable? Give
reasons.
36. An alkane C8H18 is obtained as the only product on subjecting a primary alkyl
halide to Wurtz reaction. On monobromination this alkane yields a single isomer
of a tertiary bromide. Write the structure of alkane and the tertiary bromide.
37. The ring systems having following characteristics are aromatic.
Planar ring containing conjugated π bonds.
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(i)
(ii)
Complete delocalisation of the π−electrons in ring system i.e. each
atom in the ring has unhybridised p-orbital, and
(iii)
Presence of (4n+2) π−electrons in the ring where n is an integer
(n = 0, 1, 2,...........) [Huckel rule].
Using this information classify the following compounds as aromatic/nonaromatic.
(A)
(B)
no
38. Which of the following compounds are aromatic according to Huckel’s rule?
(E)
(D)
(C)
(F)
39. Suggest a route to prepare ethyl hydrogensulphate (CH3–CH2–OSO2—OH)
starting from ethanol (C2H 5OH).
167
Hydrocarbons
IV. Matching Type
40. Match the reagent from Column I which on reaction with CH 3—CH=CH 2 gives
some product given in Column II as per the codes given below :
Column I
Column II
(i)
O3/Zn + H2O
(a)
Acetic acid and CO 2
(ii)
KMnO4/H
(b)
Propan-1-ol
(iii)
KMnO4/OH–
(c)
Propan-2-ol
(iv)
H2O/H+
(d)
Acetaldehyde and formaldehyde
(v)
B2H6/NaOH and H 2O 2
(e)
Propane-1,2-diol
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+
41. Match the hydrocarbons in Column I with the boiling points given in Column II.
Column I
Column II
(i)
n–Pentane
(a)
282.5 K
(ii)
iso-Pentane
(b)
309 K
(iii)
neo-Pentane
(c)
301 K
42. Match the following reactants in Column I with the corresponding reaction
products in Column II.
Column I
Column II
AlCl 3
Benzene + Cl2 ⎯⎯⎯
⎯
→
(a)
Benzoic acid
AlCl3
Benzene + CH3Cl ⎯⎯⎯⎯
→
(b)
Methyl phenyl ketone
(iii)
AlCl 3
Benzene + CH3COCl ⎯⎯⎯
⎯
→
(c)
Toluene
(iv)
KMnO /NaOH
Toluene ⎯⎯⎯
4
⎯⎯⎯⎯
→
(d)
Chlorobenzene
(e)
Benzene hexachloride
(i)
(ii)
43. Match the reactions given in Column I with the reaction types in Column II.
no
Column I
Column II
+
(i)
CH2
H
CH2 + H2O ⎯⎯⎯
→ CH3CH2OH
(a)
Hydrogenation
(ii)
CH2
Pd
CH2 + H2 ⎯⎯⎯
→ CH3—CH3
(b)
Halogenation
(iii)
CH2
CH2 + Cl2 ⎯⎯→ Cl—CH2—CH2—Cl
(c)
Polymerisation
(iv)
Cu tube
⎯⎯
→ C6H6
3 CH CH ⎯⎯⎯
Heat
(d)
Hydration
(e)
Condensation
Exemplar Problems, Chemistry 168
V. Assertion and Reason Type
In the following questions a statement of assertion (A) followed by a statement
of reason (R) is given. Choose the correct option out of the choices given
below each question.
44. Assertion (A) : The compound cyclooctane has the following structural
formula :
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It is cyclic and has conjugated 8π-electron system but it is not
an aromatic compound.
Reason (R) :
(4n + 2) π electrons rule does not hold good and ring is not
planar.
(i)
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
45. Assertion (A) : Toluene on Friedal Crafts methylation gives o– and p–xylene.
Reason (R) :
CH3-group bonded to benzene ring increases electron density
at o– and p– position.
(i)
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
46. Assertion (A) : Nitration of benzene with nitric acid requires the use of
concentrated sulphuric acid.
Reason (R) :
The mixture of concentrated sulphuric acid and concentrated
+
nitric acid produces the electrophile, NO2 .
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
no
(i)
47. Assertion (A) : Among isomeric pentanes, 2, 2-dimethylpentane has highest
boiling point.
Reason (R) :
Branching does not affect the boiling point.
(i)
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
169
Hydrocarbons
VI. Long Answer Type
48. An alkyl halide C 5H 11Br (A) reacts with ethanolic KOH to give an alkene ‘B’,
which reacts with Br2 to give a compound ‘C’, which on dehydrobromination
gives an alkyne ‘D’. On treatment with sodium metal in liquid ammonia one
mole of ‘D’ gives one mole of the sodium salt of ‘D’ and half a mole of hydrogen
gas. Complete hydrogenation of ‘D’ yields a straight chain alkane. Identify
A,B, C and D. Give the reactions invovled.
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49. 896 mL vapour of a hydrocarbon ‘A’ having carbon 87.80% and hydrogen
12.19% weighs 3.28g at STP. Hydrogenation of ‘A’ gives 2-methylpentane.
Also ‘A’ on hydration in the presence of H 2SO4 and HgSO4 gives a ketone ‘B’
having molecular formula C6H12O. The ketone ‘B’ gives a positive iodoform
test. Find the structure of ‘A’ and give the reactions involved.
50. An unsaturated hydrocarbon ‘A’ adds two molecules of H2 and on reductive
ozonolysis gives butane-1,4-dial, ethanal and propanone. Give the structure
of ‘A’, write its IUPAC name and explain the reactions involved.
no
51. In the presence of peroxide addition of HBr to propene takes place according
to anti Markovnikov’s rule but peroxide effect is not seen in the case of HCl
and HI. Explain.
Exemplar Problems, Chemistry 170
ANSWERS
I. Multiple Choice Questions (Type-I)
1. (iv)
2. (i)
3. (ii)
4. (i)
7. (iii)
8. (ii)
9. (iv)
10. (iii)
5. (i)
6. (iv)
II. Multiple Choice Questions (Type-II)
12. (iii), (iv)
13. (iii), (iv)
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11. (iii), (iv)
14. (i), (iv)
15. (i), (iii)
16. (i), (iii)
17. (i), (iii)
18. (i), (iii)
19. (ii), (iii)
III. Short Answer Type
20.
Both alkenes and arenes are electron-rich. Therefore undergo electrophilic
reactions. Olefins undergo addition reactions because addition of a reagent
to an olefin gives a more stable product as sp2 hybridisation changes to
sp3 hybridisation. Addition to the double bond of an arene would give a
product with less or no resonance stability hence addition is difficult
arenes. On the other hand in substitution reaction resonance stabilisation
is retained therefore, arenes undergo substitution reaction.
21.
2-Butene is capable of showing geometrical isomerism.
22.
The rotation about C—C bond is restricted because of repulsion between
electron cloud of C—H bonds on either carbon atoms.
24.
Bond dissociation energy is least for HI and maximum for HCl therefore,
order of reactivity will be HI > HBr > HCl.
25.
Propyl chloride forms less stable CH 3—CH2—CH 2 carbocation with
⊕
anhydrous AlCl3 which rearranges to a more stable
carbocation and gives isopropylbenzene as the product of the reaction.
27.
The +R effect of —OCH3 > —Cl and —NO2 has a – R effect. Relative reactivity
of the substituted benzene rings is as follows :
no
C6H5—OCH3 > C6H 5—Cl > C6H 5–NO 2
28.
Halogens attached to benzene rings exert – I and +R effect. +R effect
dominates – I effect and increases the electron density at ortho and
para positions of the benzene ring with respect to halogens.
33.
2-Methyl butane is
and C given below :
. Possible compounds are A, B
171
Hydrocarbons
Nine possibilities for compound ‘A’
because nine methyl hydrogens
are present in 2-methylbutane.
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Two possibilities for ‘B’ compound
because two CH hydrogens are
present in 2-methylbutane.
Only one possibility for ‘C’
compound because one CH
hydrogen is present in 2methylbutane.
Relative amounts of A, B
and C compounds
Relative amount
=
number of hydrogen × relative reactivity
A (1°)
B (2°)
C (3°)
9×1= 9
2×3.8 = 7.6
1×5=5
Total Amount of monohaloginated compounds = 9 + 7.6 + 5 = 21.6
=
9
× 100 = 41.7%
21.6
Percentage of B
=
7.6
× 100 = 35.2%
21.6
Percentage of C
=
5
× 100 = 23.1%
21.6
no
Percentage of A
35.
Radical I is tertiary where as radical II is primary. Radical I is more stable
due to hyperconjugation.
Exemplar Problems, Chemistry 172
36.
A
= Planar ring, all atoms of the ring sp2 hybridised, has six delocalised
π electrons, follows Huckel rule. It is aromatic.
B
= Has six π electrons, but the delocalisation stops at sp3 hybridised
CH2- carbon. Hence, not aromatic.
C
= Six delocalised π-electrons (4 π electrons + 2 unshared electrons on
negatively charged carbon) in a planar ring, follows Huckel’s rule.
It is aromatic.
D
= Has only four delocalised π-electrons. It is non aromatic.
E
= Six delocalised π-electrons follows Huckel’s rule. π electrons are in
sp2 hybridised orbitals, conjugation all over the ring because of
positively charged carbon. The ring is planar hence is aromatic.
F
= Follows Huckel’s rule, has 2 π electrons i.e. (4n+2) π-electrons where
(n=0), delocalised π-electrons. It is aromatic.
G
= 8π electrons, does not follow Huckel’s rule i.e., (4n+2) π-electrons
rule. It is not aromatic.
A
= Has 8π electrons, does not follow Huckel rule. Orbitals of one carbon
atom are not in conjugation. It is not aromatic.
B
= Has 6π delocalised electrons. Hence, is aromatic.
C
= Has 6π electrons in conjugation but not in the ring. Non aromatic.
D
= 10π electrons in planar rings, aromatic.
E
= Out of 8π electrons it has delocalised 6π electrons in one six
membered planar ring, which follows Huckel’s rule due to which it
will be aromatic.
F
= 14 π electrons are in conjugation and are present in a ring. Huckel’s
rule is being followed. Compound will be aromatic if ring is planar.
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37.
38.
no
IV. Matching Type
40.
(i) → (d)
(ii) → (a)
(iii) → (e)
(iv) → (c)
(v) → (b)
41.
(i) → (b)
(ii) → (c)
(iii) → (a)
42.
(i) → (d)
(ii) → (c)
(iii) → (b)
(iv) → (a)
43.
(i) → (d)
(ii) → (a)
(iii) → (b)
(iv) → (c)
173
Hydrocarbons
V. Assertion and Reason Type
44. (i)
45. (i)
46. (i)
47. (iii)
VI. Long Answer Type
48.
Br in CS
alc.KOH
2 ⎯⎯⎯
2 → C H Br
C5H11 Br ⎯⎯⎯
⎯⎯→ Alkene (C5H 10) ⎯⎯⎯
5
10
2
(A)
(B)
(C)
Na–liq.NH
1
H
2 2
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Alc.KOH
3
⎯⎯⎯⎯⎯
→ C5H7–Na +
–2HBr → C5H8 ⎯⎯⎯⎯⎯⎯
D (Alkyne)
Sodium alkylide
The reactions suggest that (D) is a terminal alkyne. This means triple
bond is at the end of the chain. It could be either (I) or (II).
CH 3— CH2—CH2—CH2 ≡ CH
I
II
Since alkyne ‘D’ on hydrogenation yields straight chain alkane, therefore
structure I is the structure of alkyne (D).
Hence, the structures of A, B and C are as follows :
(A) CH3—CH2—CH2—CH2—CH2Br
(B) CH3—CH2—CH2—CH
CH2
(C) CH3—CH2—CH2—CH (Br)—CH2Br
49.
Step I
896 mL vapour of CxH y (A) weighs 3.28 g
22700 mL vapour of CxH y (A) weighs
3.28×22700
–1
g mol = 83.1 g mol–1
896
Step II
(%)
Atomic
mass
C
87.8
12
7.31
1
3
H
12.19
1
12.19
1.66
4.98 ≈ 5
no
Element
Relative ratio
Relative no.
of atoms
Empirical formula of ‘A’ C3H 5
Empirical formula mass = 35 + 5 = 41 u
Molecular mass
83.1
n = Empirical formula mass = 41 = 2.02 ≈ 2
Exemplar Problems, Chemistry 174
Simplest
ratio
⇒ Molecular mass is double of the empirical formula mass.
∴ Molecular Formula is C 6H 10
Step III
Structure of 2-methylpentane is
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Hence, the molecule has a five carbon chain with a methyl group at the
second carbon atom.
‘A’ adds a molecule of H 2O in the presence of Hg 2+ and H+, it should be an
alkyne. Two possible structures for ‘A’ are :
or
I
II
Since the ketone (B) gives a positive iodoform test, it should contain a
—COCH3 group. Hence the structure of ketone is as follows :
Therefore structure of alkyne is II.
50.
Two molecules of hydrogen add on ‘A’ this shows that ‘A’ is either an
alkadiene or an alkyne.
On reductive ozonolysis ‘A’ gives three fragments, one of which is
dialdehyde. Hence, the molecule has broken down at two sites. Therefore,
‘A’ has two double bonds. It gives the following three fragments :
OHC—CH 2—CH2—CHO, CH3CHO
and
CH3—CO—CH 3
Hence, its structure as deduced from the three fragments must be
no
(A)
Reactions
(A)
Ozone
⎯⎯⎯⎯
→
Zn/ H2 O
⎯⎯⎯⎯⎯
→ CH3—CHO + OHC—CH2—CH2—CHO +
175
Hydrocarbons
Unit
14
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ENVIR
ONMENT
AL
ENVIRONMENT
ONMENTAL
CHEMIS
TRY
CHEMISTRY
I. Multiple Choice Questions (Type-I)
1.
2.
3.
Which of the following gases is not a green house gas?
(i)
CO
(ii)
O3
(iii)
CH4
(iv)
H2O vapour
Photochemical smog occurs in warm, dry and sunny climate. One of the
following is not amongst the components of photochemical smog, identify it.
(i)
NO2
(ii)
O3
(iii)
SO2
(iv)
Unsaturated hydrocarbon
Which of the following statements is not true about classical smog?
Its main components are produced by the action of sunlight on
emissions of automobiles and factories.
no
(i)
4.
(ii)
Produced in cold and humid climate.
(iii)
It contains compounds of reducing nature.
(iv)
It contains smoke, fog and sulphur dioxide.
Biochemical Oxygen Demand, (BOD) is a measure of organic material present
in water. BOD value less than 5 ppm indicates a water sample to be __________.
(i)
rich in dissolved oxygen.
6.
7.
8.
(iii)
highly polluted.
(iv)
not suitable for aquatic life.
Which of the following statements is wrong?
(i)
Ozone is not responsible for green house effect.
(ii)
Ozone can oxidise sulphur dioxide present in the atmosphere to sulphur
trioxide.
(iii)
Ozone hole is thinning of ozone layer present in stratosphere.
(iv)
Ozone is produced in upper stratosphere by the action of UV rays on
oxygen.
Sewage containing organic waste should not be disposed in water bodies
because it causes major water pollution. Fishes in such a polluted water die
because of
(i)
Large number of mosquitoes.
(ii)
Increase in the amount of dissolved oxygen.
(iii)
Decrease in the amount of dissolved oxygen in water.
(iv)
Clogging of gills by mud.
Which of the following statements about photochemical smog is wrong?
(i)
It has high concentration of oxidising agents.
(ii)
It has low concentration of oxidising agent.
(iii)
It can be controlled by controlling the release of NO 2, hydrocarbons,
ozone etc.
(iv)
Plantation of some plants like pinus helps in controlling photochemical
smog.
The gaseous envelope around the earth is known as atmosphere. The lowest
layer of this is extended upto 10 km from sea level, this layer is _________.
(i)
Stratosphere
(ii)
Troposphere
(iii)
Mesosphere
(iv)
Hydrosphere
Dinitrogen and dioxygen are main constituents of air but these do not react
with each other to form oxides of nitrogen because _________.
no
9.
poor in dissolved oxygen.
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5.
(ii)
(i)
the reaction is endothermic and requires very high temperature.
(ii)
the reaction can be initiated only in presence of a catalyst.
(iii)
oxides of nitrogen are unstable.
(iv)
N2 and O2 are unreactive.
10. The pollutants which come directly in the air from sources are called primary
pollutants. Primary pollutants are sometimes converted into secondary
pollutants. Which of the following belongs to secondary air pollutants?
177 Environmental Chemistry
(i)
CO
(ii)
Hydrocarbon
(iii)
Peroxyacetyl nitrate
(iv)
NO
11. Which of the following statements is correct?
Ozone hole is a hole formed in stratosphere from which ozone oozes out.
(ii)
Ozone hole is a hole formed in the troposphere from which ozone oozes
out.
(iii)
Ozone hole is thinning of ozone layer of stratosphere at some places.
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(i)
(iv)
Ozone hole means vanishing of ozone layer around the earth completely.
12. Which of the following practices will not come under green chemistry?
(i)
If possible, making use of soap made of vegetable oils instead of using
synthetic detergents.
(ii)
Using H2O 2 for bleaching purpose instead of using chlorine based
bleaching agents.
(iii)
Using bicycle for travelling small distances instead of using petrol/
diesel based vehicles.
(iv)
Using plastic cans for neatly storing substances.
II. Multiple Choice Questions (Type-II)
In the following questions two or more options may be correct.
13. Which of the following conditions shows the polluted environment.
(i)
pH of rain water is 5.6.
(ii)
amount of carbondioxide in the atmosphere is 0.03%.
(iii)
biochemical oxygen demand 10 ppm.
(iv)
eutrophication.
14. Phosphate containing fertilisers cause water pollution. Addition of such
compounds in water bodies causes __________.
enhanced growth of algae.
no
(i)
(ii)
decrease in amount of dissolved oxygen in water.
(iii)
deposition of calcium phosphate.
(iv)
increase in fish population.
15. The acids present in acid rain are _________.
(i)
Peroxyacetylnitrate
(ii)
H2CO3
Exemplar Problems, Chemistry 178
(iii)
HNO3
(iv)
H 2SO4
16. The consequences of global warming may be _________.
(i)
increase in average temperature of the earth
(ii)
melting of Himalayan Glaciers.
(iii)
increased biochemical oxygen demand.
(iv)
eutrophication.
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III. Short Answer Type
17. Green house effect leads to global warming. Which substances are responsible
for green house effect?
18. Acid rain is known to contain some acids. Name these acids and where from
they come in rain?
19. Ozone is a toxic gas and is a strong oxidising agent even then its presence in
the stratosphere is very important. Explain what would happen if ozone from
this region is completely removed?
20. Dissolved oxygen in water is very important for aquatic life. What processes
are responsible for the reduction of dissolved oxygen in water?
21. On the basis of chemical reactions involved, explain how do
chlorofluorocarbons cause thinning of ozone layer in stratosphere.
22. What could be the harmful effects of improper management of industrial and
domestic solid waste in a city?
23. During an educational trip, a student of botany saw a beautiful lake in a
village. She collected many plants from that area. She noticed that villagers
were washing clothes around the lake and at some places waste material
from houses was destroying its beauty.
no
After few years, she visited the same lake again. She was surprised to find that
the lake was covered with algae, stinking smell was coming out and its water
had become unusable.Can you explain the reason for this condition of the
lake?
24. What are biodegradable and non-biodegradable pollutants?
25. What are the sources of dissolved oxygen in water?
26. What is the importance of measuring BOD of a water body?
27. Why does water covered with excessive algal growth become polluted?
179 Environmental Chemistry
28. A factory was started near a village. Suddenly villagers started feeling the
presence of irritating vapours in the village and cases of headache, chest
pain, cough, dryness of throat and breathing problems increased. Villagers
blamed the emissions from the chimney of the factory for such problems.
Explain what could have happened. Give chemical reactions for the support
of your explanation.
29. Oxidation of sulphur dioxide into sulphur trioxide in the absence of a
catalyst is a slow process but this oxidation occurs easily in the atmosphere.
Explain how does this happen. Give chemical reactions for the conversion
of SO2 into SO 3.
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30. From where does ozone come in the photochemical smog?
31. How is ozone produced in stratosphere?
32. Ozone is a gas heavier than air. Why does ozone layer not settle down near
the earth?
33. Some time ago formation of polar stratospheric clouds was reported over
Antarctica. Why were these formed? What happens when such clouds break
up by warmth of sunlight?
34. A person was using water supplied by Municipality. Due to shortage of water
he started using underground water. He felt laxative effect. What could be
the cause?
IV. Matching Type
In the following questions more than one option of Column I and Column
II may match.
35. Match the terms given in Column I with the compounds given in Column II.
Column I
Column II
Acid rain
(a)
CHCl2 – CHF2
(ii)
Photochemical smog
(b)
CO
(iii)
Combination with
haemoglobin
(c)
CO2
(iv)
Depletion of ozone layer
(d)
SO2
(e)
Unsaturated hydrocarbons
no
(i)
36. Match the pollutant(s) in Column I with the effect(s) in Column II.
Column I
Column II
(i)
Oxides of sulphur
(a)
Global warming
(ii)
Nitrogen dioxide
(b)
Damage to kidney
Exemplar Problems, Chemistry 180
(iii)
Carbon dioxide
(c)
‘Blue baby’ syndrome
(iv)
Nitrate in drinking water
(d)
Respiratory diseases
(v)
Lead
(e)
Red haze in traffic and
congested areas
37. Match the activity given in Column I with the type of pollution created by it
given in Column II.
Column I (Activity)
Releasing gases to the atmosphere
after burning waste material
containing sulphur.
(a) Water pollution
(ii)
Using carbamates as pesticides
(b) Photochemical smog,
damage to plant life,
corrosion to building
material, induce breathing
problems, water pollution
(iii)
Using synthetic detergents for
washing clothes
(c) Damaging ozone layer
(iv)
Releasing gases produced by
automobiles and factories in the
atmosphere.
(d) May cause nerve diseases
in human.
(v)
Using chlorofluorocarbon compounds
for cleaning computer parts
(e) Classical smog, acid rain,
water pollution, induce
breathing problems,
damage to buildings,
corrosion of metals.
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(i)
Column II (Effect)
38. Match the pollutants given in Column I with their effects given in Column II.
Column I
Column II
(i)
Phosphate fertilisers in water
(a) BOD level of water increases
(ii)
Methane in air
(b) Acid rain
(iii)
Synthetic detergents in water
(c)
(iv)
Nitrogen oxides in air
(d) Eutrophication
no
Global warming
V. Assertion and Reason Type
In the following questions a statement of Assertion (A) followed by a statement
of Reason (R) is given. Choose the correct option out of the choices given
below each question.
39. Assertion (A): Green house effect was observed in houses used to grow
plants and these are made of green glass.
181 Environmental Chemistry
Reason (R) :
Green house name has been given because glass houses are
made of green glass.
(i)
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
40. Assertion (A) : The pH of acid rain is less than 5.6.
Carbon dioxide present in the atmosphere dissolves in rain
water and forms carbonic acid.
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Reason (R) :
(i)
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
41. Assertion (A) : Photochemical smog is oxidising in nature.
Reason (R) :
Photochemical smog contains NO 2 and O3, which are formed
during the sequence of reactions.
(i)
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
42. Assertion (A) : Carbon dioxide is one of the important greenhouse gases.
Reason (R) :
It is largely produced by respiratory function of animals and
plants.
(i)
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
43. Assertion (A) : Ozone is destroyed by solar radiation in upper stratosphere.
Reason (R) :
Thinning of the ozone layer allows excessive UV radiations
to reach the surface of earth.
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
no
(i)
44. Assertion (A) : Excessive use of chlorinated synthetic pesticides causes soil
and water pollution.
Reason (R) :
Such pesticides are non-biodegradable.
Exemplar Problems, Chemistry 182
(i)
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
45. Assertion (A) : If BOD level of water in a reservoir is less than 5 ppm it is
highly polluted.
Reason (R) :
High biological oxygen demand means low activity of bacteria
in water.
Both A and R are correct and R is the correct explanation of A.
(ii)
Both A and R are correct but R is not the correct explanation of A.
(iii)
Both A and R are not correct.
(iv)
A is not correct but R is correct.
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(i)
VI. Long Answer Type
46. How can you apply green chemistry for the following :
(i)
to control photochemical smog.
(ii)
to avoid use of halogenated solvents in drycleaning and that of chlorine
in bleaching.
(iii)
to reduce use of synthetic detergents.
(iv)
to reduce the consumption of petrol and diesel.
47. Green plants use carbon dioxide for photosynthesis and return oxygen to
the atmosphere, even then carbon dioxide is considered to be responsible for
green house effect. Explain why?
48. Explain how does green house effect cause global warming.
49. A farmer was using pesticides on his farm. He used the produce of his farm
as food for rearing fishes. He was told that fishes were not fit for human
consumption because large amount of pesticides had accumulated in the
tissues of fishes. Explain how did this happen?
no
50. For dry cleaning, in the place of tetrachloroethane, liquefied carbon dioxide
with suitable detergent is an alternative solvent. What type of harm to the
environment will be prevented by stopping use of tetrachloroethane? Will
use of liquefied carbon dioxide with detergent be completely safe from the
point of view of pollution? Explain.
183 Environmental Chemistry
ANSWERS
I. Multiple Choice Questions (Type-I)
1. (i)
7. (ii)
2. (iii)
8. (ii)
3. (i)
9. (i)
4. (i)
10. (iii)
5. (i)
11. (iii)
6. (iii)
12. (iv)
II. Multiple Choice Questions (Type-II)
14. (i), (ii)
15. (ii), (iii), (iv)
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13. (iii), (iv)
16. (i), (ii)
III. Short Answer Type
17.
Trapping of heat by green house gases, namely carbon dioxide, methane,
nitrous oxide, ozone and chlorofluorocarbons.
19.
[Hint : Ozone prevents harmful UV radiations of the Sun from reaching
to the Earth’s surface, thereby it protects life from bad effects of UV
radiations.]
21.
CFC’s are stable compounds. These undergo decomposition in presence
of sunlight, as shown below :
UV
Reactions:CF2Cl2 (g) ⎯⎯⎯
→ Cl (g) + CF2Cl (g)
Cl (g) + O3 (g) ⎯→ ClO (g) + O2 (g)
ClO (g) + O (g) ⎯→ Cl (g) + O2 (g)
Chain reactions continue in which ozone layer is depleted.
23.
[Hint : Process of eutrophication is responsible for this. Explain the effect
of accumulation of phosphate from detergents and organic matter entering
into the lake along with domestic waste.]
24.
Biodegradable - which are decomposed by bacteria.
Non-biodegradable - which cannot be decomposed by bacteria.
Sources of dissolved oxygen in water
no
25.
26.
(i)
Photosynthesis
(ii)
Natural aeration
(iii)
Mechanical aeration
BOD is the measure of level of pollution caused by organic biodegradable
material. Low value of BOD indicates that water contains less organic
matter.
Exemplar Problems, Chemistry 184
IV. Matching Type
35.
(i) → (c), (d)
(ii) → (e), (d)
(iii) → (b)
(iv) → (a)
36.
(i) → (d)
(ii) → (e)
(iii) → (a)
(iv) → (c)
(v) → (b)
37.
(i) → (e)
(ii) → (d)
(iii) → (a)
(iv) → (b)
(v) → (c)
38.
(i) → (a), (d)
(ii) → (c)
(iii) → (a)
(iv) → (b)
42. (ii)
43. (iv)
V. Assertion and Reason Type
40. (ii)
41. (i)
44. (i)
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39. (iii)
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45. (iii)
185 Environmental Chemistry
APPENDIX I
ELEMENTS, THEIR ATOMIC NUMBER AND MOLAR MASS
Element
Atomic
Number
Molar
mass/
(g mol–1)
Element
Ac
Al
Am
Sb
Ar
As
At
Ba
Bk
Be
Bi
Bh
B
Br
Cd
Cs
Ca
Cf
C
Ce
Cl
Cr
Co
Cu
Cm
Db
Dy
Es
Er
Eu
Fm
F
Fr
Gd
Ga
Ge
Au
Hf
Hs
He
Ho
H
In
I
Ir
Fe
Kr
La
Lr
Pb
Li
Lu
Mg
Mn
Mt
Md
89
13
95
51
18
33
85
56
97
4
83
107
5
35
48
55
20
98
6
58
17
24
27
29
96
105
66
99
68
63
100
9
87
64
31
32
79
72
108
2
67
1
49
53
77
26
36
57
103
82
3
71
12
25
109
101
227.03
26.98
(243)
121.75
39.95
74.92
210
137.34
(247)
9.01
208.98
(264)
10.81
79.91
112.40
132.91
40.08
251.08
12.01
140.12
35.45
52.00
58.93
63.54
247.07
(263)
162.50
(252)
167.26
151.96
(257.10)
19.00
(223)
157.25
69.72
72.61
196.97
178.49
(269)
4.00
164.93
1.0079
114.82
126.90
192.2
55.85
83.80
138.91
(262.1)
207.19
6.94
174.96
24.31
54.94
(268)
258.10
Mercury
Molybdenum
Neodymium
Neon
Neptunium
Nickel
Niobium
Nitrogen
Nobelium
Osmium
Oxygen
Palladium
Phosphorus
Platinum
Plutonium
Polonium
Potassium
Praseodymium
Promethium
Protactinium
Radium
Radon
Rhenium
Rhodium
Rubidium
Ruthenium
Rutherfordium
Samarium
Scandium
Seaborgium
Selenium
Silicon
Silver
Sodium
Strontium
Sulphur
Tantalum
Technetium
Tellurium
Terbium
Thallium
Thorium
Thulium
Tin
Titanium
Tungsten
Ununbium
Ununnilium
Unununium
Uranium
Vanadium
Xenon
Ytterbium
Yttrium
Zinc
Zirconium
Symbol
Atomic
Number
Hg
Mo
Nd
Ne
Np
Ni
Nb
N
No
Os
O
Pd
P
Pt
Pu
Po
K
Pr
Pm
Pa
Ra
Rn
Re
Rh
Rb
Ru
Rf
Sm
Sc
Sg
Se
Si
Ag
Na
Sr
S
Ta
Tc
Te
Tb
Tl
Th
Tm
Sn
Ti
W
Uub
Uun
Uuu
U
V
Xe
Yb
Y
Zn
Zr
80
42
60
10
93
28
41
7
102
76
8
46
15
78
94
84
19
59
61
91
88
86
75
45
37
44
104
62
21
106
34
14
47
11
38
16
73
43
52
65
81
90
69
50
22
74
112
110
111
92
23
54
70
39
30
40
Molar
mass/
(g mol–1)
200.59
95.94
144.24
20.18
(237.05)
58.71
92.91
14.0067
(259)
190.2
16.00
106.4
30.97
195.09
(244)
210
39.10
140.91
(145)
231.04
(226)
(222)
186.2
102.91
85.47
101.07
(261)
150.35
44.96
(266)
78.96
28.08
107.87
22.99
87.62
32.06
180.95
(98.91)
127.60
158.92
204.37
232.04
168.93
118.69
47.88
183.85
(277)
(269)
(272)
238.03
50.94
131.30
173.04
88.91
65.37
91.22
no
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Actinium
Aluminium
Americium
Antimony
Argon
Arsenic
Astatine
Barium
Berkelium
Beryllium
Bismuth
Bohrium
Boron
Bromine
Cadmium
Caesium
Calcium
Californium
Carbon
Cerium
Chlorine
Chromium
Cobalt
Copper
Curium
Dubnium
Dysprosium
Einsteinium
Erbium
Europium
Fermium
Fluorine
Francium
Gadolinium
Gallium
Germanium
Gold
Hafnium
Hassium
Helium
Holmium
Hydrogen
Indium
Iodine
Iridium
Iron
Krypton
Lanthanum
Lawrencium
Lead
Lithium
Lutetium
Magnesium
Manganese
Meitneium
Mendelevium
Symbol
The value given in parenthesis is the molar mass of the isotope of largest known half-life.
APPENDIX II
SOME USEFUL CONVERSION FACTORS
Common Units of Length
1 inch = 2.54 centimetres (exactly)
1 mile = 5280 feet = 1.609 kilometres
1 yard = 36 inches = 0.9144 metre
1 metre = 100 centimetres
= 39.37 inches
= 3.281 feet
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Common Unit of Mass and Weight
1 pound = 453.59 grams
1 pound = 453.59 grams = 0.45359 kilogram
1 kilogram = 1000 grams = 2.205 pounds
1 gram = 10 decigrams = 100 centigrams
= 1000 milligrams
1 gram = 6.022 × 1023 atomic mass units or u
1 atomic mass unit = 1.6606 × 10–24 gram
1 metric tonne = 1000 kilograms
= 2205 pounds
Common Unit of Volume
1 quart = 0.9463 litre
1 litre = 1.056 quarts
1 litre = 1 cubic decimetre = 1000 cubic
centimetres = 0.001 cubic metre
1 millilitre = 1 cubic centimetre = 0.001 litre
= 1.056 × 10-3 quart
1 cubic foot = 28.316 litres = 29.902 quarts
= 7.475 gallons
no
Common Units of Energy
1 joule = 1 × 107 ergs
1 thermochemical calorie** = 4.184 joules
= 4.184 × 107 ergs
= 4.129 × 10–2 litre-atmospheres
= 2.612 × 1019 electron volts
–7
1 ergs = 1 × 10 joule = 2.3901 × 10–8 calorie
1 electron volt = 1.6022 × 10–19 joule
= 1.6022 × 10–12 erg
= 96.487 kJ/mol†
1 litre-atmosphere = 24.217 calories
= 101.32 joules
= 1.0132 ×109 ergs
1 British thermal unit = 1055.06 joules
= 1.05506 ×1010 ergs
= 252.2 calories
= 1.094 yards
1 kilometre = 1000 metres
= 1094 yards
= 0.6215 mile
1 Angstrom = 1.0 × 10–8 centimetre
= 0.10 nanometre
= 1.0 × 10–10 metre
= 3.937 × 10–9 inch
Common Units of Force* and Pressure
1 atmosphere= 760 millimetres of mercury
= 1.013 × 105 pascals
= 14.70 pounds per square inch
1 bar = 105 pascals
1 torr = 1 millimetre of mercury
1 pascal = 1 kg/ms2 = 1 N/m2
Temperature
SI Base Unit: Kelvin (K)
K = -273.15°C
K = °C + 273.15
°F
= 1.8(°C) + 32
°C =
°F − 32
1.8
Force: 1 newton (N) = 1 kg m/s 2, i.e.,the force that, when applied for 1 second, gives a
1-kilogram mass a velocity of 1 metre per second.
** The amount of heat required to raise the temperature of one gram of water from 14.50C to 15.50C.
† Note that the other units are per particle and must be multiplied by 6.022 ×1023 to be strictly
comparable.
*
APPENDIX III
STANDARD POTENTIALS AT 298 K IN ELECTROCHEMICAL
Reduction half-reaction
E ⊖ /V
Reduction half-reaction
H4XeO6 + 2H+ + 2e– → XeO3 + 3H2O
+3.0
Pu4+ + e– → Pu3+
+0.97
F2 + 2e– → 2F–
+2.87
NO–3 + 4H+ + 3e– → NO + 2H2O
+0.96
O3 + 2H+ + 2e– → O2 + H2O
+2.07
2Hg2+ + 2e– → Hg 2+
2
+0.92
S2O8 + 2e– → 2SO4
+2.05
ClO– + H2O + 2e– → Cl– + 2OH–
+0.89
Ag+ + e– → Ag+
+1.98
Hg2+ + 2e– → Hg
+0.86
Co3+ + e– → Co2+
+1.81
NO–3 + 2H+ + e– → NO2 + H2O
+0.80
H2O2 + 2H+ + 2e– → 2H2O
+1.78
Ag+ + e– → Ag
+0.80
Au+ + e– → Au
+1.69
–
Hg 2+
2 +2e → 2Hg
+0.79
Pb4+ + 2e– → Pb2+
+1.67
Fe3+ + e– → Fe2+
+0.77
2HClO + 2H+ + 2e– → Cl2 + 2H2O
+1.63
BrO– + H2O + 2e– → Br– + 2OH–
+0.76
Ce4+ + e– → Ce3+
+1.61
Hg2SO4 +2e– → 2Hg + SO42–
+0.62
2HBrO + 2H+ + 2e– → Br2 + 2H2O
+1.60
–
–
MnO2–
+0.60
4 + 2H2O + 2e → MnO2 + 4OH
MnO4 + 8H+ + 5e– → Mn2+ + 4H2O
+1.51
MnO–4 + e– → MnO42–
+0.56
Mn3+ + e– → Mn2+
+1.51
I2 + 2e– → 2I–
+0.54
Au3+ + 3e– → Au
+1.40
I3 + 2e– → 3I–
+0.53
Cl2 + 2e– → 2Cl–
+1.36
Cu+ + e– → Cu
+0.52
Cr2O 7 + 14H+ + 6e– → 2Cr3+ + 7H2O
+1.33
NiOOH + H2O + e– → Ni(OH)2 + OH– +0.49
O3 + H2O + 2e– → O2 + 2OH–
+1.24
Ag2CrO4 + 2e– → 2Ag + CrO2–
4
+0.45
O2 + 4H+ + 4e– → 2H2O
+1.23
O2 + 2H2O + 4e– → 4OH–
+0.40
ClO–4 + 2H+ +2e– → ClO–3 + 2H2O
+1.23
ClO–4 + H2O + 2e– → ClO–3 + 2OH–
+0.36
MnO2 + 4H+ + 2e– → Mn2+ + 2H2O
+1.23
[Fe(CN)6]3– + e– → [Fe(CN)6]4–
+0.36
Pt2+ + 2e– → Pt
+1.20
Cu2+ + 2e– → Cu
+0.34
Br2 + 2e– → 2Br–
+1.09
Hg2Cl2 + 2e– → 2Hg + 2Cl–
+0.27
–
no
2–
2–
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2–
E ⊖ /V
–
AgCl + e– → Ag + Cl–
+0.27
S + 2e– → S2–
–0.48
Bi3+ + 3e– → Bi
+0.20
In3+ + e– → In2+
–0.49
SO42 + 4H+ + 2e– → H2SO3 + H2O
+0.17
U4+ + e– → U3+
–0.61
Cu2+ + e– → Cu+
+0.16
Cr3+ + 3e– → Cr
–0.74
Sn4+ + 2e– → Sn2+
+0.15
Zn2+ + 2e– → Zn
–0.76
AgBr + e– → Ag + Br–
+0.07
Cd(OH)2 + 2e– → Cd + 2OH–
–0.81
Ti4+ + e– → Ti3+
0.00
2H2O + 2e– → H2 + 2OH–
–0.83
2H+ + 2e– → H2
(by definition) 0.0
Cr2+ + 2e– → Cr
–0.91
Fe3+ + 3e– → Fe
–0.04
Mn2+ + 2e– → Mn
–1.18
O2 + H2O + 2e– → HO–2 + OH–
–0.08
V2+ + 2e– → V
–1.19
Pb2+ + 2e– → Pb
–0.13
Ti2+ + 2e– → Ti
–1.63
In+ + e– → In
–0.14
Al3+ + 3e– → Al
–1.66
Sn2+ + 2e– → Sn
–0.14
U3+ + 3e– → U
–1.79
AgI + e– → Ag + I–
–0.15
Sc3+ + 3e– → Sc
–2.09
Ni2+ + 2e– → Ni
–0.23
Mg2+ + 2e– → Mg
–2.36
V3+ + e– → V2+
–0.26
Ce3+ + 3e– → Ce
–2.48
Co2+ + 2e– → Co
–0.28
La3+ + 3e– → La
–2.52
In3+ + 3e– → In
–0.34
Na+ + e– → Na
–2.71
Tl+ + e– → Tl
–0.34
Ca2+ + 2e– → Ca
–2.87
PbSO4 + 2e– → Pb + SO2–
4
–0.36
Sr2+ + 2e– → Sr
–2.89
Ti3+ + e– → Ti2+
–0.37
Ba2+ + 2e– → Ba
–2.91
Cd2+ + 2e– → Cd
–0.40
Ra2+ + 2e– → Ra
–2.92
In2+ + e– → In+
–0.40
Cs+ + e– → Cs
–2.92
Cr3+ + e– → Cr2+
–0.41
Rb+ + e– → Rb
–2.93
Fe2+ + 2e– → Fe
–0.44
K+ +e– → K
–2.93
In3+ + 2e– → In+
–0.44
Li+ + e– → Li
–3.05
no
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203
Appendices
APPENDIX IV
LOGARITHMS
Sometimes, a numerical expression may involve multiplication, division or rational powers of large numbers.
For such calculations, logarithms are very useful. They help us in making difficult calculations easy. In
Chemistry, logarithm values are required in solving problems of chemical kinetics, thermodynamics,
electrochemistry, etc. We shall first introduce this concept, and discuss the laws, which will have to be
followed in working with logarithms, and then apply this technique to a number of problems to show how it
makes difficult calculations simple.
We know that
23 = 8, 32 = 9, 53 = 125, 70 = 1
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In general, for a positive real number a, and a rational number m, let am = b,
where b is a real number. In other words
the mth power of base a is b.
Another way of stating the same fact is
logarithm of b to base a is m.
If for a positive real number a, a ≠ 1
am = b,
we say that m is the logarithm of b to the base a.
b
We write this as lo g a = m ,
“log” being the abbreviation of the word “logarithm”.
Thus, we have
3
=8
2
=9
3
= 125
0
=1
log 2 8 = 3,
Since 2
log 3 9 = 2,
Since 3
log
125
= 3,
Since 5
5
log 7 1 = 0,
Since 7
Laws of Logarithms
In the following discussion, we shall take logarithms to any base a, (a > 0 and a ≠ 1)
First Law: loga (mn) = logam + logan
Proof: Suppose that logam = x and logan = y
Then ax= m, ay = n
no
Hence mn = ax.ay = ax+y
It now follows from the definition of logarithms that
loga (mn) = x + y = loga m – loga n
m
 = loga m – logan
n
Second Law: loga 
Proof: Let logam = x, logan = y
Then ax = m, ay = n
Hence
m
n
=
a
a
x
=a
y
x−y
Therefore
log a
m
 =
n
x − y = log a m − log a n
Third Law :
loga(mn) = n logam
Proof : As before, if logam = x, then ax = m
n
( )
x n
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Then m
= a
=a
nx
giving loga(mn) = nx = n loga m
Thus according to First Law: “the log of the product of two numbers is equal to the sum of their logs.
Similarly, the Second Law says: the log of the ratio of two numbers is the difference of their logs. Thus, the
use of these laws converts a problem of multiplication / division into a problem of addition/subtraction,
which are far easier to perform than multiplication/division. That is why logarithms are so useful in all
numerical computations.
Logarithms to Base 10
Because number 10 is the base of writing numbers, it is very convenient to use logarithms to the base 10.
Some examples are:
log10 10 = 1,
log10 100 = 2,
since 101 = 10
since 102 = 100
log10 10000 = 4, since 104 = 10000
log10 0.01 = –2,
since 10–2 = 0.01
log10 0.001 = –3,
since 10–3 = 0.001
and log101 = 0
since 100 = 1
The above results indicate that if n is an integral power of 10, i.e., 1 followed by several zeros or 1
preceded by several zeros immediately to the right of the decimal point, then log n can be easily found.
If n is not an integral power of 10, then it is not easy to calculate log n. But mathematicians have made
no
tables from which we can read off approximate value of the logarithm of any positive number between 1 and
10. And these are sufficient for us to calculate the logarithm of any number expressed in decimal form. For
this purpose, we always express the given decimal as the product of an integral power of 10 and a number
between 1 and 10.
Standard Form of Decimal
We can express any number in decimal form, as the product of (i) an integral power of 10, and (ii) a number
between 1 and 10. Here are some examples:
(i) 25.2 lies between 10 and 100
205
Appendices
25.2
25.2 =
10
1
× 10 = 2.52 × 10
(ii) 1038.4 lies between 1000 and 10000.
∴ 1038.4
=
1038.4
1000
× 10
3
= 1.0384 × 10
3
(iii) 0.005 lies between 0.001 and 0.01
∴
–3
–3
0.005 = (0.005 × 1000) × 10 = 5.0 × 10
(iv) 0.00025 lies between 0.0001 and 0.001
–4
–4
0.00025 = (0.00025 × 10000) × 10 = 2.5 × 10
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∴
In each case, we divide or multiply the decimal by a power of 10, to bring one non-zero digit to the left of the
decimal point, and do the reverse operation by the same power of 10, indicated separately.
Thus, any positive decimal can be written in the form
p
n = m × 10
where p is an integer (positive, zero or negative) and 1< m < 10. This is called the “standard form of n.”
Working Rule
1. Move the decimal point to the left, or to the right, as may be necessary, to bring one non-zero digit to the
left of decimal point.
2.
p
(i) If you move p places to the left, multiply by 10 .
–p
(ii) If you move p places to the right, multiply by 10 .
0
(iii) If you do not move the decimal point at all, multiply by 10 .
(iv) Write the new decimal obtained by the power of 10 (of step 2) to obtain the standard form of the
given decimal.
Characteristic and Mantissa
Consider the standard form of n
p
n = m ×10 , where 1 < m < 10
Taking logarithms to the base 10 and using the laws of logarithms
p
log n = log m + log 10
= log m + p log 10
= p + log m
no
Here p is an integer and as 1 < m < 10, so 0 < log m < 1, i.e., m lies between 0 and 1. When log n has been
expressed as p + log m, where p is an integer and 0 log m < 1, we say that p is the “characteristic” of log n and
that log m is the “mantissa of log n. Note that characteristic is always an integer – positive, negative or zero,
and mantissa is never negative and is always less than 1. If we can find the characteristics and the mantissa
of log n, we have to just add them to get log n.
Thus to find log n, all we have to do is as follows:
1. Put n in the standard form, say
n = m × 10p, 1 < m <10
Exemplar Problems, Chemistry 206
2. Read off the characteristic p of log n from this expression (exponent of 10).
3. Look up log m from tables, which is being explained below.
4. Write log n = p + log m
If the characteristic p of a number n is say, 2 and the mantissa is .4133, then we have log n = 2+
.4133 which we can write as 2.4133. If, however, the characteristic p of a number m is say –2 and the
mantissa is .4123, then we have log m = –2 + .4123. We cannot write this as –2.4123. (Why?) In order to
avoid this confusion we write 2 for –2 and thus we write log m = 2.4 1 2 3 .
Now let us explain how to use the table of logarithms to find mantissas. A table is appended at the end
of this Appendix.
Observe that in the table, every row starts with a two digit number, 10, 11, 12,... 97, 98, 99. Every
0
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column is headed by a one-digit number, 0, 1, 2, ...9. On the right, we have the section called “Mean
differences” which has 9 columns headed by 1, 2...9.
1
2
..
3
4
5
..
6
7
8
..
9
1
2
3
4
5
6
7
8
9
..
..
..
..
..
..
..
..
..
..
..
..
..
..
..
..
..
61
7853
7860 7868
7875
7882 7889
7896
7803 7810
7817
1
1
2
3
4
4
5
6
6
62
7924
7931 7935
7945
7954 7959
7966
7973 7980
7987
1
1
2
3
3
4
5
6
6
63
7993
8000 8007
8014
8021 8028
8035
8041 8048
8055
1
1
2
3
3
4
5
6
6
..
..
..
..
..
..
..
..
..
..
..
..
..
..
..
..
..
..
..
..
Now suppose we wish to find log (6.234). Then look into the row starting with 62. In this row, look at
the number in the column headed by 3. The number is 7945. This means that
log (6.230) = 0.7945*
But we want log (6.234). So our answer will be a little more than 0.7945. How much more? We look this
up in the section on Mean differences. Since our fourth digit is 4, look under the column headed by 4 in the
Mean difference section (in the row 62). We see the number 3 there. So add 3 to 7945. We get 7948. So we
finally have
log (6.234) = 0.7948.
Take another example. To find log (8.127), we look in the row 81 under column 2, and we find 9096. We
continue in the same row and see that the mean difference under 7 is 4. Adding this to 9096, and we get
9100. So, log (8.127) = 0.9100.
Finding N when log N is given
We have so far discussed the procedure for finding log n when a positive number n given. We now turn to its
converse i.e., to find n when log n is given and give a method for this purpose. If log n = t, we sometimes say
n = antilog t. Therefore our task is given t, find its antilog. For this, we use the ready-made antilog tables.
no
Suppose log n = 2.5372.
To find n, first take just the mantissa of log n. In this case it is .5372. (Make sure it is positive.) Now
take up antilog of this number in the antilog table which is to be used exactly like the log table. In the
antilog table, the entry under column 7 in the row .53 is 3443 and the mean difference for the last digit 2 in
that row is 2, so the table gives 3445. Hence,
antilog (.5372) = 3.445
Now since log n = 2.5372, the characteristic of log n is 2. So the standard form of n is given by
207
Appendices
2
n = 3.445 × 10
or n = 344.5
Illustration 1
If log x = 1.0712, find x.
Solution: We find that the number corresponding to 0712 is 1179. Since characteristic of log x is 1, we have
x = 1.179 × 101
= 11.79
Illustration 2
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If log x = 2.1352, find x.
Solution: From antilog tables, we find that the number corresponding to 1352 is 1366. Since the characteristic
is 2 i.e., –2, so
x = 1.366 × 10–2 = 0.01366
Use of Logarithms in Numerical Calculations
Illustration 1
Find 6.3 × 1.29
Solution: Let x = 6.3 × 1.29
Then log x = log (6.3 × 1.29) = log 6.3 + log 1.29
Now,
log 6.3 = 0.7993
log 1.29 = 0.1106
∴ log x = 0.9099,
Taking antilog
x = 8.127
Illustration 2
1.5
Find
(1.23)
11.2 × 23.5
3
(1.23)2
Solution: Let x =
11.2 × 23.5
no
3
Then log x = log
=
=
3
2
3
2
(1.23)2
11.2 × 23.5
log 1.23 – log (11.2 × 23.5)
log 1.23 – log 11.2 – 23.5
Exemplar Problems, Chemistry 208
Now,
log 1.23 = 0.0899
3
2
log 1.23 = 0.13485
log 11.2 = 1.0492
log 23.5 = 1.3711
log x = 0.13485 – 1.0492 – 1.3711
= 3.71455
∴ x = 0.005183
Illustration 3
(71.24) × 56
Find
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5
(2.3) × 21
7
5
(71.24) × 56
Solution: Let x =
Then log x =
=
=
(2.3) × 21
7
1
2
1
2
5
2
 (71.24)5 × 56 

7
 (2.3) × 21 
log 
5
[log (71.24) + log
log 71.24 +
1
7
56 − log (2.3) − log 21]
log 56 −
7
(1.7482) −
7
4
2
log 2.3 −
1
4
log 21
Now, using log tables
log 71.24 = 1.8527
log 56 = 1.7482
log 2.3 = 0.3617
log 21 = 1.3222
∴ log x =
5
2
log (1.8527) +
1
4
2
(0.3617) −
1
4
(1.3222)
= 3.4723
no
∴ x = 2967
209
Appendices
LOGARITHMS
Table 1
N
0
2
3
4
10
0000 0043
0086
0128
0170
11
0414 0453
0492
0531
0569
0792 0828
0864
0899
5
6
7
8
9
1
2
3
4
5
7
8
9
8
13
12
17
16
21 26
2O 24
6
30
28
34 38
32 36
9
0212
0253 0294 0334 0374
5
4
0607
0645 0682 0719 0755
4
4
8
7
12
11
16
15
20
18
23
22
27
26
31 35
29 33
0969
1004 1038 1072 1106
3
3
7
7
11
10
14
14
18
17
21
20
25
24
28 32
27 31
1303
1335 1367 1399 1430
3
3
6
7
10
10
13
13
16
16
19
19
23
22
26 29
25 29
1614
1644 1673 1703 1732
3
3
6
6
9
9
12
12
15
14
19
17
22
20
25 28
23 26
1903
1931 1959 1987 2014
3
3
6
6
9
8
11
11
14
14
17
17
20
19
23 26
22 25
2175
2201 2227 2253 2279
3
3
6
5
8
8
11
10
14
16
13 16
19
18
22 24
21 23
2430
2455 2480 2504 2529
3
3
5
5
8
8
10
10
13
12
15
15
18
17
20 23
20 22
2672
2695 2718 2742 2765
2
2
5
4
7
7
9
9
12 14
11 14
17
16
19 21
18 21
2900
2923 2945 2967 2989
2
2
4
4
7
6
9
8
11
11
13
13
16
15
18 20
17 19
0934
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12
1
13
14
15
16
17
18
19
1139 1173
1461 1492
1761 1790
2041 2068
2304 2330
2553 2577
2788 2810
1206
1523
1818
2095
2355
2601
2833
1239
1553
1847
2122
2380
2625
2856
1271
1584
1875
2148
2405
2648
2878
3010 3032
3222 3243
3054
3263
3075
3284
3096
3304
3118
3324
3139 3160 3181 3201
3345 3365 3385 3404
2
2
4
4
6
6
8
8
11
10
13
12
15
14
17 19
16 18
22
23
3424 3444
3617 3636
3464
3655
3483
3674
3502
3692
3522
3711
3541 3560 3579 3598
3729 3747 3766 3784
2
2
4
4
6
6
8
7
10
9
12
11
14
13
15 17
15 17
24
25
3802 3820
3979 3997
3838
4014
3856
4031
3874
4048
3892
4065
3909 3927 3945 3962
4082 4099 4116 4133
2
2
4
3
5
5
7
7
9
9
11
10
12
12
14 16
14 15
26
27
4150 4166
4314 4330
4183
4346
4200
4362
4216
4378
4232
4393
4249 4265 4281 4298
4409 4425 4440 4456
2
2
3
3
5
5
7
6
8
8
10
9
11
11
13 15
13 14
28
29
4472 4487
4624 4639
4502
4654
4518
4669
4533
4683
4548
4698
4564 4579 4594 4609
4713 4728 4742 4757
2
1
3
3
5
4
6
6
8
7
9
9
11
10
12 14
12 13
30
4771 4786
4800
4814
4829
4843
4857 4871 4886 4900
1
3
4
6
7
9
10
11 13
31
32
4914 4928
5051 5065
4942 4955
5079 5092
4969
5105
4983
5119
4997 5011 5024 5038
5132 5145 5159 5172
1
1
3
3
4
4
6
5
7
7
8
8
10
9
11 12
11 12
33
34
5185 5198
5315 5328
5211
5340
5224
5353
5237
5366
5250
5378
5263 5276 5289 5302
5391 5403 5416 5428
1
1
3
3
4
4
5
5
6
6
8
8
9
9
10 12
10 11
35
5441 5453
5465
5478
5490
5502
5514 5527 5539 5551
1
2
4
5
6
7
9
10 11
36
37
5563 5575
5682 5694
5587
5705
5599
5717
5611
5729
5623
5740
5635 5647 5658 5670
5752 5763 5775 5786
1
1
2
2
4
3
5
5
6
6
7
7
8
8
10 11
9 10
38
39
5798 5809
5911 5922
5821
5933
5832
5944
5843
5955
5855
5966
5866 5877 5888 5899
5977 5988 5999 6010
1
1
2
2
3
3
5
4
6
5
7
7
8
8
9 10
9 10
40
6021 6031
6042
6053
6064
6075
6085 6096 6107 6117
1
2
3
4
5
6
8
9 10
41
42
6128 6138
6232 6243
6149
6253
6160
6263
6170
6274
6180
6284
6191 6201 6212 6222
6294 6304 6314 6325
1
1
2
2
3
3
4
4
5
5
6
6
7
7
8
8
9
9
43
44
6335 6345
6435 6444
6355
6454
6365
6464
6375
6474
6385
6484
6395 6405 6415 6425
6493 6503 6513 6522
1
1
2
2
3
3
4
4
5
5
6
6
7
7
8
8
9
9
no
20
21
45
6532 6542
6551
6561
6471
6580
6590 6599 6609 6618
1
2
3
4
5
6
7
8
9
46
47
6628 6637
6721 6730
6646
6739
6656
6749
6665
6758
6675
6767
6684 6693 6702 6712
6776 6785 6794 6803
1
1
2
2
3
3
4
4
5
5
6
5
7
6
7
7
8
8
48
49
6812 6821
6902 6911
6830
6920
6839
6928
6848
6937
6857
6946
6866 6875 6884 6893
6955 6964 6972 6981
1
1
2
2
3
3
4
4
4
4
5
5
6
6
7
7
8
8
LOGARITHMS
0
2
3
4
5
6
1
2
3
4
5
6
7
8
9
50
51
6990 6998
7076 7084
7007
7093
7016
7101
7024
7110
7033
7118
7042 7050 7059 7067
7126 7135 7143 7152
1
1
2
2
3
3
3
3
4
4
5
5
6
6
7
7
8
8
52
53
54
7160 7168
7243 7251
7324 7332
7177
7259
7340
7185
7267
7348
7193
7275
7356
7202
7284
7364
7210 7218 7226 7235
7292 7300 7308 7316
7372 7380 7388 7396
1
1
1
2
2
2
2
2
2
3
3
3
4
4
4
5
5
5
6
6
6
7
6
6
7
7
7
55
56
57
7404 7412
7482 7490
7559 7566
7419
7497
7574
7427
7505
7582
7435
7513
7589
7443
7520
7597
7451 7459 7466 7474
7528 7536 7543 7551
7604 7612 7619 7627
1
1
1
2
2
2
2
2
2
3
3
3
4
4
4
5
5
5
5
5
5
6
6
6
7
7
7
7634 7642
7709 7716
7649
7723
7657
7731
7664
7738
7672
7745
7679 7686 7694 7701
7752 7760 7767 7774
1
1
1
1
2
2
3
3
4
4
4
4
5
5
6
6
7
7
7782
7853
7924
7993
7789
7860
7931
8000
7796
7768
7938
8007
7803
7875
7945
8014
7810
7882
7952
8021
7818
7889
7959
8028
7825
7896
7966
8035
7846
7917
7987
8055
1
1
1
1
1
1
1
1
2
2
2
2
3
3
3
3
4
4
3
3
4
4
4
4
5
5
5
5
6
6
6
5
6
6
6
6
8062 8069
8075
8082
8089
8096
8102 8109 8116 8122
1
1
2
3
3
4
5
5
6
8129
8195
8261
8325
8388
8136
8202
8267
8331
8395
8142
8209
8274
8338
8401
8149
8215
8280
8344
8407
8156
8222
8287
8351
8414
8162
8228
8293
8357
8420
8169
8235
8299
8363
8426
8176
8241
8306
8370
8432
8182
8248
8312
8376
8439
8189
8254
8319
8382
8445
1
1
1
1
1
1
1
1
1
1
2
2
2
2
2
3
3
3
3
2
3
3
3
3
3
4
4
4
4
4
5
5
5
4
4
5
5
5
5
5
6
6
6
6
6
8451
8513
8573
8633
8692
8457
8519
8579
8639
8698
8463
8525
8585
8645
8704
8470
8531
8591
8651
8710
8476
8537
8597
8657
8716
8482
8543
8603
8663
8722
8488
8549
8609
8669
8727
8494
8555
8615
8675
8733
8500
8561
8621
8681
8739
8506
8567
8627
8686
8745
1
1
1
1
1
1
1
1
1
1
2
2
2
2
2
2
2
2
2
2
3
3
3
3
3
4
4
4
4
4
4
4
4
4
4
5
5
5
5
5
6
5
5
5
5
8751
8808
8865
8921
8976
8756
8814
8871
8927
8982
8762
8820
8876
8932
8987
8768
8825
8882
8938
8993
8774
8831
8887
8943
8998
8779
8837
8893
8949
9004
8785
8842
8899
8954
9009
8791
8848
8904
8960
9015
8797
8854
8910
8965
9020
8802
8859
8915
8971
9025
1
1
1
1
1
1
1
1
1
1
2
2
2
2
2
2
2
2
2
2
3
3
3
3
3
3
3
3
3
3
4
4
4
4
4
5
5
4
4
4
5
5
5
5
5
9031
9085
9138
9191
9243
9036
9090
9143
9196
9248
9042
9096
9149
9201
9253
9047
9101
9154
9206
9258
9053
9106
9159
9212
9263
9058
9112
9165
9217
9269
9063
9117
9170
9222
9274
9069
9122
9175
9227
9279
9074
9128
9180
9232
9284
9079
9133
9186
9238
9289
1
1
1
1
1
1
1
1
1
1
2
2
2
2
2
2
2
2
2
2
3
3
3
3
3
3
3
3
3
3
4
4
4
4
4
4
4
4
4
4
5
5
5
5
5
9294
9345
9395
9445
9494
9299
9350
9400
9450
9499
9304
9355
9405
9455
9504
9309
9360
9410
9460
9509
9315
9365
9415
9465
9513
9320
9370
9420
9469
9518
9325
9375
9425
9474
9523
9330
9380
9430
9479
9528
9335
9385
9435
9484
9533
9340
9390
9440
9489
9538
1
1
0
0
0
1
1
1
1
1
2
2
1
1
1
2
2
2
2
2
3
3
2
2
2
3
3
3
3
3
4
4
3
3
3
4
4
4
4
4
5
5
4
4
4
9542
9590
9638
9685
9731
9547
9595
9643
9689
9736
9552
9600
9647
9694
9741
9557
9605
9652
9699
9745
9562
9609
9657
9703
9750
9566
9614
9661
9708
9754
9571
9619
9666
9713
9759
9576
9624
9671
9717
9763
9581
9628
9675
9722
9768
9586
9633
9680
9727
9773
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
2
2
2
2
2
2
2
2
2
2
3
3
3
3
3
3
3
3
3
3
4
4
4
4
4
4
4
4
4
4
9791
9836
9881
9926
9969
9795
9841
9886
9930
9974
9800
9845
9890
9934
9978
9805
9850
9894
9939
9983
9809
9854
9899
9943
9987
9814
9859
9903
9948
9997
9818
9863
9908
9952
9996
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
2
2
2
2
2
2
2
2
2
2
3
3
3
3
3
3
3
3
3
3
4
4
4
4
3
4
4
4
4
4
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
1
7
8
9
tt ©
o N
be C
re ER
pu T
bl
is
he
d
N
no
Table 1 continued
9777
9823
9868
9912
9956
9782
9827
9872
9917
9961
9786
9832
9877
9921
9965
7832
7903
7973
8041
7839
7910
7980
8048
ANTILOGARITHMS
Table 2
0
1
2
3
4
5
6
7
8
9
1
2
3
4
5
6
7
8
9
00
.01
.02
.03
.04
.05
.06
.07
.08
.09
1000
1023
1047
1072
1096
1122
1148
1175
1202
1230
1002
1026
1050
1074
1099
1125
1151
1178
1205
1233
1005
1028
1052
1076
1102
1127
1153
1180
1208
1236
1007
1030
1054
1079
1104
1130
1156
1183
1211
1239
1009
1033
1057
1081
1107
1132
1159
1186
1213
1242
1012
1035
1059
1084
1109
1135
1161
1189
1216
1245
1014
1038
1062
1086
1112
1138
1164
1191
1219
1247
1016
1040
1064
1089
1114
1140
1167
1194
1222
1250
1019
1042
1067
1091
1117
1143
1169
1197
1225
1253
1021
1045
1069
1094
1119
1146
1172
1199
1227
1256
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
3
3
.10
.11
.12
.13
.14
.15
.16
.17
.18
.19
1259
1288
1318
1349
1380
1413
1445
1479
1514
1549
1262
1291
1321
1352
1384
1416
1449
1483
1517
1552
1265
1294
1324
1355
1387
1419
1452
1486
1521
1556
1268
1297
1327
1358
1390
1422
1455
1489
1524
1560
1271
1300
1330
1361
1393
1426
1459
1493
1528
1563
1274
1303
1334
1365
1396
1429
1462
1496
1531
1567
1276
1306
1337
1368
1400
1432
1466
1500
1535
1570
1279
1309
1340
1371
1403
1435
1469
1503
1538
1574
1282
1312
1343
1374
1406
1439
1472
1507
1542
1578
1285
1315
1346
1377
1409
1442
1476
1510
1545
1581
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
3
2
2
2
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
.20
.21
.22
.23
.24
1585
1622
1660
1698
1738
1589
1626
1663
1702
1742
1592
1629
1667
1706
1746
1596
1633
1671
1710
1750
1600
1637
1675
1714
1754
1603
1641
1679
1718
1758
1607
1644
1683
1722
1762
1611
1648
1687
1726
1766
1614
1652
1690
1730
1770
1618
1656
1694
1734
1774
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
2
2
2
2
2
2
2
2
2
2
2
2
2
2
3
3
3
3
3
3
3
3
3
3
3
3
3
4
4
.25
.26
.27
.28
.29
1778
1820
1862
1905
1950
1782
1824
1866
1910
1954
1786
1828
1871
1914
1959
1791
1832
1875
1919
1963
1795
1837
1879
1923
1968
1799
1841
1884
1928
1972
1803
1845
1888
1932
1977
1807
1849
1892
1936
1982
1811
1854
1897
1941
1986
1816
1858
1901
1945
1991
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
2
2
2
2
2
2
2
2
2
2
2
3
3
3
3
3
3
3
3
3
3
3
3
4
4
4
4
4
4
4
.30
.31
.32
.33
.34
.35
.36
.37
.38
.39
1995
2042
2089
2138
2188
2239
2291
2344
2399
2455
2000
2046
2094
2143
2193
2244
2296
2350
2404
2460
2004
2051
2099
2148
2198
2249
2301
2355
2410
2466
2009
2056
2104
2153
2203
2254
2307
2360
2415
2472
2014
2061
2109
2158
2208
2259
2312
2366
2421
2477
2018
2065
2113
2163
2213
2265
2317
2371
2427
2483
2023
2070
2118
2168
2218
2270
2323
2377
2432
2489
2028
2075
2123
2173
2223
2275
2328
2382
2438
2495
2032
2080
2128
2178
2228
2280
2333
2388
2443
2500
2037
2084
2133
2183
2234
2286
2339
2393
2449
2506
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
5
4
4
4
4
5
5
5
5
5
5
.40
.41
.42
.43
.44
.45
.46
.47
.48
2512
2570
2630
2692
2754
2818
2884
2951
3020
2518
2576
2636
2698
2761
2825
2891
2958
3027
2523
2582
2642
2704
2767
2831
2897
2965
3034
2529
2588
2649
2710
2773
2838
2904
2972
3041
2535
2594
2655
2716
2780
2844
2911
2979
3048
2541
2600
2661
2723
2786
2851
2917
2985
3055
2547
2606
2667
2729
2793
2858
2924
2992
3062
2553
2612
2673
2735
2799
2864
2931
2999
3069
2559
2618
2679
2742
2805
2871
2938
3006
3076
2564
2624
2685
2748
2812
2877
2944
3013
3083
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2
2
2
2
2
2
2
2
2
2
2
2
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
4
4
4
4
4
4
4
4
4
4
4
4
4
4
5
5
5
5
5
5
5
5
5
5
5
5
6
5
5
6
6
6
6
6
6
6
.49
3090 3097
3105
3112
3119
3126
3133 3141 3148 3155
1
1
2
3
3
4
5
6
6
no
tt ©
o N
be C
re ER
pu T
bl
is
he
d
N
ANTILOGARITHMS
Table 2 continued
0
1
2
3
4
5
6
7
8
9
1
2
3
4
5
6
7
8
9
.50
.51
.52
.53
.54
.55
.56
3162
3236
3311
3388
3467
3548
3631
3170
3243
3319
3396
3475
3556
3639
3177
3251
3327
3404
3483
3565
3648
3184
3258
3334
3412
3491
3573
3656
3192
3266
3342
3420
3499
3581
3664
3199
3273
3350
3428
3508
3589
3673
3206
3281
3357
3436
3516
3597
3681
3214
3289
3365
3443
3524
3606
3690
3221
3296
3373
3451
3532
3614
3698
3228
3304
3381
3459
3540
3622
3707
1
1
1
1
1
1
1
1
2
2
2
2
2
2
2
2
2
2
2
2
3
3
3
3
3
3
3
3
4
4
4
4
4
4
4
4
5
5
5
5
5
5
5
5
5
6
6
6
6
6
6
6
6
6
7
7
7
7
7
7
7
7
8
.57
.58
.59
3715 3724
3802 3811
3890 3899
3733
3819
3908
3741
3828
3917
3750
3837
3926
3758
3846
3936
3767 3776 3784 3793
3855 3864 3873 3882
3945 3954 3963 3972
1
1
1
2
2
2
3
3
3
3
4
4
4
4
5
5
5
5
6
6
6
7
7
7
8
8
8
.60
.61
.62
.63
.64
.65
.66
.67
.68
.69
3981
4074
4169
4266
4365
4467
4571
4677
4786
4898
3990
4083
4178
4276
4375
4477
4581
4688
4797
4909
3999
4093
4188
4285
4385
4487
4592
4699
4808
4920
4009
4102
4198
4295
4395
4498
4603
4710
4819
4932
4018
4111
4207
4305
4406
4508
4613
4721
4831
4943
4027
4121
4217
4315
4416
4519
4624
4732
4842
4955
4036
4130
4227
4325
4426
4529
4634
4742
4853
4966
4046
4140
4236
4335
4436
4539
4645
4753
4864
4977
4055
4150
4246
4345
4446
4550
4656
4764
4875
4989
4064
4159
42S6
4355
4457
4560
4667
4775
4887
5000
1
1
1
1
1
1
1
1
1
1
2
2
2
2
2
2
2
2
2
2
3
3
3
3
3
3
3
3
3
3
4
4
4
4
4
4
4
4
4
5
5
5
5
5
5
5
5
5
6
6
6
6
6
6
6
6
6
7
7
7
6
7
7
7
7
7
7
8
8
8
7
8
8
8
8
8
9
9
9
9
8
9
9
9
9
9
10
10
10
10
.70 5012 5023
.71 5129 5140
.72 5248 5260
.73 5370 5383
.74 5495 5508
.75 5623 5636
.76 5754 5768
.77 5888 5902
.78 6026 6039
.79 6166 6180
5035
5152
5272
5395
5521
5649
5781
5916
6053
6194
5047
5164
5284
5408
5534
5662
5794
5929
6067
6209
5058
5176
5297
5420
5546
5675
5808
5943
6081
6223
5070
5188
5309
5433
5559
5689
5821
5957
6095
6237
5082
5200
5321
5445
5572
5702
5834
5970
6109
6252
5093
5212
5333
5458
5585
5715
5848
5984
6124
6266
5105
5224
5346
5470
5598
5728
5861
5998
6138
6281
5117
5236
5358
5483
5610
5741
5875
6012
6152
6295
1
1
1
1
1
1
1
1
1
1
2
2
2
3
3
3
3
3
3
3
4
4
4
4
4
4
4
4
4
4
5
5
5
5
5
5
5
5
6
6
6
6
6
6
6
7
7
7
7
7
7
7
7
8
8
8
8
8
8
9
8
8
9
9
9
9
9
10
10
10
9
10
10
10
10
10
11
11
11
11
11
11
11
11
12
12
12
12
13
13
.80
.81
.82
.83
.84
6310
6457
6607
6761
6918
6324
6471
6622
6776
6934
6339
6486
6637
6792
6950
6353
6501
6653
6808
6966
6368
6516
6668
6823
6982
6383
6531
6683
6839
6998
6397
6546
6699
6855
7015
6412
6561
6714
6871
7031
6427
6577
6730
6887
7047
6442
6592
6745
6902
7063
1
2
2
2
2
3
3
3
3
3
4
5
5
5
5
6
6
6
6
6
7
8
8
8
8
9
9
9
9
10
10
11
11
11
11
12 13
12 14
12 14
1314
13 15
.85
.86
.87
.88
.89
7079
7244
7413
7586
7762
7096
7261
7430
7603
7780
7112
7278
7447
7621
7798
7129
7295
7464
7638
7816
7145
7311
7482
7656
7834
7161
7328
7499
7674
7852
7178
7345
7516
7691
7870
7194
7362
7534
7709
7889
7211
7379
7551
7727
7907
7228
7396
7568
7745
7925
2
2
2
2
2
3
3
3
4
4
5
5
5
5
5
7
7
7
7
7
8
8
9
9
9
10
10
10
11
11
12
12
12
12
13
13
13
14
14
14
15
15
16
16
16
.90
.91
.92
.93
.94
7943
8128
8318
8511
8710
7962
8147
8337
8531
8730
7980
8166
8356
8551
8750
7998
8185
8375
8570
8770
8017
8204
8395
8590
8790
8035
8222
8414
8610
8810
8054
8241
8433
8630
8831
8072
8260
8453
8650
8851
8091
8279
8472
8670
8872
8110
8299
8492
8690
8892
2
2
2
2
2
4
4
4
4
4
6
6
6
6
6
7
8
8
8
8
9
9
10
10
10
11
11
12
12
12
13
13
14
14
14
15
15
15
16
16
17
17
17
18
18
8974
9183
9397
9616
9840
8995
9204
9419
9638
9863
9016
9226
9441
9661
9886
9036
9247
9462
9683
9908
9057
9268
9484
9705
9931
9078
9290
9506
9727
9954
9099
9311
9528
9750
9977
2
2
2
2
2
4
4
4
4
5
6
6
7
7
7
8
8
9
9
9
10
11
11
11
11
12
13
13
13
14
15
15
15
16
16
17
17
17
18
18
19
19
20
20
20
no
tt ©
o N
be C
re ER
pu T
bl
is
he
d
N
.95
.96
.97
.98
.99
8913
9120
9333
9550
9772
8933
9141
9354
9572
9795
8954
9162
9376
9594
9817
tt ©
o N
be C
re ER
pu T
bl
is
he
d
no
NOTES
tt ©
o N
be C
re ER
pu T
bl
is
he
d
no
NOTES
tt ©
o N
be C
re ER
pu T
bl
is
he
d
no
NOTES